Not applicable.
Embodiments described herein generally relate to downhole pumping systems and methods. More particularly, embodiments described herein relate to systems and methods for deliquifying subterranean gas wells to enhance production.
Geological structures that yield gas typically produce water and other liquids that accumulate at the bottom of the wellbore. The liquids typically comprise hydrocarbon condensate (e.g., relatively light gravity oil) and interstitial water in the reservoir. The liquids accumulate in the wellbore in two forms, both as single phase liquid entering from the reservoir and as condensing liquids, falling back in the wellbore. The condensing liquids actually enter the wellbore as a vapor and as they travel up the wellbore, they drop below their respective dew points and condense. In either case, the higher density liquid-phase, being essentially discontinuous, must be transported to the surface by the gas.
In some hydrocarbon producing wells that produce both gas and liquid, the formation gas pressure and volumetric flow rate are sufficient to lift the produced liquids to the surface. In such wells, accumulation of liquids in the wellbore generally does not hinder gas production. However, in the event the gas phase does not provide sufficient transport energy to lift the liquids out of the well (i.e. the formation gas pressure and volumetric flow rate are not sufficient to lift the produced liquids to the surface), the liquid will accumulate in the well bore.
In many cases, the hydrocarbon well may initially produce gas with sufficient pressure and volumetric flow to lift produced liquids to the surface, however, over time, the produced gas pressure and volumetric flow rate decrease until they are no longer capable of lifting the produced liquids to the surface. Specifically, as the life of a natural gas well matures, reservoir pressures that drive gas production to surface decline, resulting in lower production. At some point, the gas velocities drop below the “Critical Velocity” (CV), which is the minimum velocity required to carry a droplet of water to the surface. As time progresses these droplets accumulate in the bottom of the wellbore. The accumulation of liquids in the well impose an additional back-pressure on the formation and may begin to cover the gas producing portion of the formation and detrimentally affect the production capacity of the well. Once the liquid will no longer flow with the produced gas to the surface, the well will eventually become “loaded” as the liquid hydrostatic head begins to overcome the lifting action of the gas flow, at which point the well is “killed” or “shuts itself in.” Thus, the accumulation of liquids such as water in a natural gas well tends to reduce the quantity of natural gas that can be produced from the well. Consequently, it may become necessary to use artificial lift techniques to remove the accumulated liquid from the wellbore to restore the flow of gas from the formation. The process for removing such accumulated liquids from a wellbore is commonly referred to as “deliquification.”
For oil wells that primarily produce single phase liquids (oil and water) with a minimal amount of entrained gas, there are numerous artificial lift techniques. The most commonly employed type of artificial lift requires pulling 30 foot tubing joints from the well, attaching a fluid pump to the lowermost joint, and running the pump downhole on the string of tubing joints. The fluid pump may be driven by jointed rods attached to a beam pump, a downhole electric motor supplied with electrical power from the surface via wires banded to the outside of the tubing string, or a surface hydraulic pump displacing a power fluid to the downhole fluid pump via multiple hydraulic lines. Although there are several types of artificial lift used in lifting oil, they usually require an expensive method of deployment consisting of workover rigs, coiled tubing units, cable spoolers, and multiple personnel on-site.
Initially, artificial lift techniques employed with oil producing wells were used to deliquify gas producing wells (i.e., remove liquids from gas producing wells). However, the adaptation of existing oilfield artificial lift technologies for gas producing wells generated a whole new set of challenges. The first challenge was commercial. When employing artificial lift techniques in an oil well, revenue is immediately generated—valuable oil is lifted to the surface. In contrast, when deliquifying a gas well, additional expense is generated mostly from non-revenue generating liquids—typically, water and small amounts of condensed light hydrocarbons are lifted to the surface. The benefit, however, is the ability to maintain and potentially increase the production of gas for extended time, thereby creating additional recoverable reserves. Typically, at 100 psi downhole pressure, the critical velocity, and hence need for artificial lift, occurs at less than 300 mcfd. One challenge is that large remaining reserve potentials with lower per well revenue streams are needed to justify the price of installing traditional artificial lift technologies.
The second major shortcoming of the existing artificial lift technologies is the lack of design for dealing with three phase flow, with the largest percentage being the gas phase. For example, many conventional artificial lift pumps gas lock or cavitate when pumping fluids comprising more than about 30% gas by volume. However, in many gas wells, the pump may experience churn fluid flow where the pump intake may experience transitions between 100% gas and 100% liquid over a few seconds. In general, the goal of a downhole fluid pump is to physically lower the fluid level or hydrostatic in the wellbore as close to the pump intake as possible. Unfortunately, most conventional artificial lift technologies cannot achieve this goal and thus are not fit for purpose.
With well economics driving limited choices for deliquification, one lower cost option that has been investigated is called “plunger lift.” In a plunger lift system, a solid round metal plug is placed inside the tubing at the bottom of the well, and liquids are allowed to accumulate on top of the plug. Then a controller shuts in the well via a shutoff valve and allows pressure to build and then releases the plunger to come to surface, pushing the fluids above it. When the shutoff valve is closed, the pressure at the bottom of the well usually builds up slowly over time as fluids and gas pass from the formation into the well. When the shutoff valve is opened, the pressure at the well head is lower than the bottomhole pressure, so that the pressure differential causes the plunger to travel to the surface. Plunger lift is basically a cyclic “bucketing” of fluids to surface. Since the driver is the wellbore pressure it is directly proportional to the amount of liquid it can lift. Also, the older the well, the longer shut-in times are required to build pressure. Besides the safety risks of launching a metal plug to surface at velocities around 1,000 feet per minute, the plunger requires high manual intervention and only removes a small fraction of the liquid column to surface.
In one embodiment described herein, a hydraulic fluid distribution system for alternating the supply of hydraulic fluid between a first chamber and a second chamber comprises a mechanical switch including a first valve, a first actuation pin extending axially from the first valve, and a second actuation pin extending axially from the first valve. The first valve includes an inlet port in fluid communication with a hydraulic fluid supply passage, a first outlet port, and a second outlet port. The first valve has a first position with the inlet port in fluid communication with the first outlet port and a second position with the inlet port in fluid communication with the second outlet port. The first actuation pin is configured to move in a first axial direction to transition the first valve from the second position to the first position, and the second actuation pin is configured to move in a second axial direction to transition the first valve from the first position to the second position. In addition, the distribution system comprises a second valve having a first position that allows fluid communication between the first outlet port of the first valve and the first chamber and a second position that allows fluid communication between the second outlet port of the first valve and the second chamber. The second chamber is in fluid communication with a hydraulic fluid return passage when the second valve is in the first position and the first chamber is in fluid communication with the hydraulic fluid return passage when the second valve is in the second position.
In another embodiment described herein, a reciprocating pump for pumping a fluid comprises a first piston chamber and a first piston disposed in the first piston chamber. In addition, the reciprocating pump comprises a second piston chamber and a second piston disposed in the second piston chamber. Further, the reciprocating pump comprises a hydraulic fluid distribution system positioned between the first piston chamber and the second piston chamber. A first section of the first piston chamber extends axially from the first piston to the hydraulic fluid distribution system and a first section of the second piston chamber extends axially from the second piston to the hydraulic fluid distribution system. Still further, the reciprocating pump comprises a connecting rod extending axially from the first piston through the hydraulic fluid distribution system to the second piston. Moreover, the reciprocating pump comprises a first pushrod extending axially from the first section of the first piston chamber into the hydraulic fluid distribution system. The reciprocating pump also comprises a second pushrod extending axially from the first section of the second piston chamber into the hydraulic fluid distribution system. The hydraulic fluid distribution system comprises a mechanical switch including an inlet port in fluid communication with a hydraulic fluid supply passage, a first outlet port, and a second outlet port. The mechanical switch has a first position with the inlet port in fluid communication with the first outlet port and a second position with the inlet port in fluid communication with the second outlet port. The hydraulic fluid distribution system also comprises a first valve having a first position that allows fluid communication between the first outlet port of the mechanical switch and the first section of the first chamber and a second position that allows fluid communication between the second outlet port of the mechanical switch and the first section of the second chamber. The first piston is configured to axially impact the first pushrod to transition the mechanical switch from the second position to the first position and the second piston is configured to axially impact the second pushrod to transition the mechanical switch from the first position to the second position.
In yet another embodiment described herein, a method for actuating a reciprocating pump comprises (a) supplying hydraulic fluid to a mechanical switch. In addition, the method comprises (b) impacting a first pushrod with a first piston of the reciprocating pump to transition the mechanical switch to a first position. Further, the method comprises (c) flowing hydraulic fluid from the mechanical switch to a first chamber containing the first piston while the mechanical switch is in the first position. Still further, the method comprises (d) flowing hydraulic fluid from a second chamber containing a second piston to a hydraulic fluid return passage while the mechanical switch is in the first position.
Embodiments described herein comprise a combination of features and advantages intended to address various shortcomings associated with certain prior devices, systems, and methods. The foregoing has outlined rather broadly the features and technical advantages of the invention in order that the detailed description of the invention that follows may be better understood. The various characteristics described above, as well as other features, will be readily apparent to those skilled in the art upon reading the following detailed description, and by referring to the accompanying drawings. It should be appreciated by those skilled in the art that the conception and the specific embodiments disclosed may be readily utilized as a basis for modifying or designing other structures for carrying out the same purposes of the invention. It should also be realized by those skilled in the art that such equivalent constructions do not depart from the spirit and scope of the invention as set forth in the appended claims.
For a detailed description of the preferred embodiments of the invention, reference will now be made to the accompanying drawings in which:
The following discussion is directed to various embodiments of the invention. Although one or more of these embodiments may be preferred, the embodiments disclosed should not be interpreted, or otherwise used, as limiting the scope of the disclosure, including the claims. In addition, one skilled in the art will understand that the following description has broad application, and the discussion of any embodiment is meant only to be exemplary of that embodiment, and not intended to intimate that the scope of the disclosure, including the claims, is limited to that embodiment.
Certain terms are used throughout the following description and claims to refer to particular features or components. As one skilled in the art will appreciate, different persons may refer to the same feature or component by different names. This document does not intend to distinguish between components or features that differ in name but not function. The drawing figures are not necessarily to scale. Certain features and components herein may be shown exaggerated in scale or in somewhat schematic form and some details of conventional elements may not be shown in interest of clarity and conciseness.
In the following discussion and in the claims, the terms “including” and “comprising” are used in an open-ended fashion, and thus should be interpreted to mean “including, but not limited to . . . . ” Also, the term “couple” or “couples” is intended to mean either an indirect or direct connection. Thus, if a first device couples to a second device, that connection may be through a direct connection, or through an indirect connection via other devices, components, and connections. In addition, as used herein, the terms “axial” and “axially” generally mean along or parallel to a central axis (e.g., central axis of a body or a port), while the terms “radial” and “radially” generally mean perpendicular to the central axis. For instance, an axial distance refers to a distance measured along or parallel to the central axis, and a radial distance means a distance measured perpendicular to the central axis.
As previously described, the accumulation of liquids such as water in a natural gas well tends to reduce the quantity of natural gas that can be produced from the well. Consequently, artificial lift techniques may be necessary to remove the accumulated liquid from the wellbore to restore the flow of gas from the formation. However, many conventional artificial lift techniques are cost prohibitive, require complicated deployment operations, are not suited for handling three phase flow, present safety risks, or are inefficient (e.g., only removes a small fraction of the liquid column to surface). Accordingly, there is a need in the art for improved systems and methods for deliquifying wells. Embodiments described herein are designed and configured to address the various shortcomings associated with certain prior devices, systems, and methods.
Referring now to
Wellbore 20 traverses an earthen formation 12 comprising a production zone 13. Casing 21 lines wellbore 20 and includes perforations 22 that allow fluids 14 (e.g., water, gas, etc.) to pass from production zone 13 into wellbore 20. System 10 extends into wellbore 20 through an injector head 50 coupled to a wellhead 24 from which casing 21 extends. In this embodiment, a blowout preventer 25 sits atop wellhead 24, and thus, system 10 extends through injector head 50, blowout preventer 25, and wellhead 24 into casing 21.
As shown in
During deliquification operations, fluids 14 in the bottom of wellbore 20 are pumped through conduit 40 to the surface 11 with pump 100. In general, system 10 may be employed to lift and remove fluids from any type of well including, without limitation, oil producing wells, natural gas producing wells, methane producing wells, propane producing wells, or combinations thereof. However, embodiments of system 10 described herein are particularly suited for deliquification of gas wells. In this embodiment, wellbore 20 is gas well, and thus, fluids 14 include water, hydrocarbon condensate, gas, and possibly small amounts of oil. Pump 100 may remain deployed in well 20 for the life of the well 20, or alternatively, be removed from well 20 once production of well 20 has been re-established. To enhance the volumetric flow rate of well fluids 14 removed from wellbore 20 and pumped to the surface 11, pump 100 preferably has an outer diameter that is maximized or as large as reasonably possible relative to the inner diameter of casing 21.
It should be appreciated that deployment of system 10 and deliquification pump 100 via vehicle 30 eliminates the need for construction and/or use of a rig. In other words, system 10 and pump 100 may be deployed in a “rigless” manner. As used herein, the term “rigless” is used to refer to an operation, process, apparatus or system that does not require the construction or use of a workover rig that includes the derrick or mast, and the drawworks. By eliminating the need for a workover rig for deployment, system 10 offers the potential to provide a more economically feasible means for deliquifying relatively low production gas wells.
Referring still to
As previously described, conduit 40 is used to deploy and position pump 100 downhole, as well provide a flow line or path for fluids pumped by pump 100 to the surface 11. A plurality of energy conductors or wires are provided in conduit 40 (e.g., embedded within the wall of conduit 40) or coupled to conduit 40 (e.g., coupled to the outside of conduit 40) for providing electrical power from the surface 11 to deliquification pump 100 to power pump and components thereof. In general, conduit 40 may comprise any suitable conduit capable of supplying electrical power to downhole pump 100 including, without limitation, coiled steel tubing, spoolable composite tubing, a cable with a flow bore, etc.
Referring now to
Due to the length of deliquification pump 100, it is illustrated in six longitudinally broken sectional views, vis-à-vis
Although
Although components of deliquification pump 100 may be configured differently, the basic operation of pump 100 remains the same. In particular, well fluid 14 in wellbore 20 pass through separator 400, which separates larger solids (e.g., sand, rock chips, etc.) from well fluid 14 to form a solids-free or substantially solids-free fluid 15, which may also be referred to as “clean” fluid 15. Clean fluid 15 output from separator 400 is sucked into fluid end pump 110 and pumped to the surface 11 through coupling 45 and conduit 40. Fluid end pump 110 is driven by hydraulic pump 200, which is driven by electric motor 300. Conductors disposed in or coupled to conduit 40 provide electrical power downhole to motor 300. Compensator 350 provides a reservoir for hydraulic fluid, which can flow to and from hydraulic pump 200 and motor 300 as needed. Deliquification pump 100 is particularly designed to lift substantially solids-free fluid 15, which may include liquid and gaseous phases (e.g., water and gas), in wellbore 20 to the surface 11 in the event the gas pressure in wellbore 20 is insufficient to remove the liquids in fluid 14 to the surface 11 (i.e., wellbore 20 is a relatively low pressure well). As will be described in more detail below, use of hydraulic pump 200 in conjunction with fluid end pump 110 offers the potential to generate the relatively high fluid pressures necessary to force or eject relatively low volumes of well fluids 15 to the surface 11.
Referring now to
In this embodiment, housing 120 is formed from a plurality of tubular segments connected together end-to-end. Consequently, housing 120 is modular and may be broken down into various subcomponents as necessary for maintenance or repair (e.g., replacement of piston seals, etc.).
Fluid end pump 110 also includes a first or upper piston 600 slidingly disposed in first chamber 121 and a second or lower piston 600′ slidingly disposed in second chamber 125. As will be described in more detail below, pistons 600, 600′ are identical. Pistons 600, 600′ are connected by an elongate connecting rod 180 that extends axially through distribution system 130.
Piston 600 divides upper chamber 121 into two sections or subchambers—a well fluids section 121a extending axially from upper valve assembly 500 to piston 600, and a hydraulic fluid chamber 121b extending axially from piston 600 to distribution system 130. Likewise, piston 600′ divides lower chamber 125 into two sections or subchambers—a well fluids section 125a extending axially from lower valve assembly 500′ to piston 600′, and a hydraulic fluid chamber 125b extending axially from piston 600′ to distribution system 130. Together, housing 120, piston 600, and valve assembly 500 define section 121a; and together, housing 120, piston 600′, and valve assembly 500′ define section 125a. In general, inlet valve 520 of valve assembly 500, 500′ controls the flow of well fluids 15 into chamber section 121a, 125a, respectively, and outlet valve 560 of valve assembly 500, 500′ controls the flow of well fluids out of chamber section 121a, 125a, respectively.
Referring still to
Inlet passage 111 supplies well fluids that have been filtered by separator 400 to inlet valves 520, and outlet passage 112 supplies pressurized well fluids from outlet valves 560 to conduit 40. More specifically, substantially solids-free well fluids 15 are output from separator 400 and flow through a well fluids flow passage 116 in a distributor 115 coupled to lower valve assembly 500′ and axially positioned between fluid end pump 110 and hydraulic pump 200 (
Outlet passage 112 is in fluid communication with conduit 40 (via coupling 45), outlet valve 560 of upper valve assembly 500, and outlet valve of lower valve assembly 500′. Thus, outlet passage 112 places both outlet valves 560 in fluid communication with conduit 40. Outlet valves 560 of valve assemblies 500, 500′ control the flow of well fluids out of chamber sections 121a, 125a, respectively. As will be described in more detail below, well fluids 15 are pumped by fluid end pump 110 from chamber sections 121a, 125a through outlet valves 560, outlet passage 112, and conduit 40 to the surface 11.
Referring still to
During pumping operations, hydraulic pump 200 provides pressurized hydraulic fluid to distribution system 130 via fluid passage 113. Distribution system 130 alternates the supply of pressurized hydraulic fluid between chambers 121b, 125b to drive the axial reciprocation of pistons 600, 600′ in chambers 121, 125, respectively. In addition, distribution system 130 allows fluid to exit the section 125b, 121b that is not being supplied pressurized hydraulic fluid.
As distribution system 130 supplies pressurized hydraulic fluid to chamber 121b, piston 600 is urged axially in a first direction (upward in
Referring still to
As previously described, as pistons 600, 600′ move axially in the first direction (upward in
As pistons 600, 600′ reciprocate within chambers 121, 125, well fluids 15 are sucked into sections 121a, 125a from well fluids flow passage 116 and inlet passage 111, respectively, in an alternating fashion, and pumped from sections 125a, 121a, respectively, to outlet passage 112 and conduit 40 in an alternating fashion. In this manner, fluid end pump 110 pumps well fluids 15 through conduit 40 to the surface 11. Since fluid end pump 110 is a double acting reciprocating pump, well fluids 15 are pumped from fluid end pump 110 to the surface 11 when pistons 600, 600′ move axially in either direction (the first direction or the second direction), and well fluids 15 are sucked from separator 400 into fluid end pump 110 when pistons 600, 600′ move axially in either direction (the first direction or the second direction).
Referring now to
Mechanical switch 140 is seated in chamber 132, and includes a first pushrod 141, a second pushrod 142, a first actuation pin 143, a second actuation pin 144, and a hydraulic fluid valve 150. Pins 143, 144 are axially positioned between pushrods 141, 142, and valve 150 is axially positioned between pins 143, 144. First pushrod 141 extends axially through body 131 and has a first end 141a disposed in section 121b of chamber 121 and a second end 141b axially adjacent first actuation pin 143. Second pushrod 142 extends axially through body 131 and has a first end 142a disposed in section 125b of chamber 125 and a second end 142b axially adjacent second actuation pin 144. Each pin 143, 144 has a first end axially adjacent end 141b, 142b, respectively, and a second end extending into valve 150. As will be described in more detail below, pushrods 141, 142 and pins 143, 144 reciprocate axially relative to body 131.
Valve 150 includes a valve cage 151 and a ball 155. Valve cage 151 has an inner cavity 152, a hydraulic fluid inlet port 153, a first hydraulic fluid outlet port 154, and a second hydraulic fluid outlet port 156. Inlet port 153 is in fluid communication with cavity 152 and hydraulic fluid supply passage 113, and thus, allows fluid communication therebetween. Outlet port 154 is in fluid communication with cavity 152 and first hydraulic fluid passage 134, and outlet port 156 is in fluid communication with cavity 152 and second hydraulic fluid passage 135. One end of each pin 143, 144 extends axially into port 153, 154, respectively, axially adjacent ball 155. However, pins 143, 144 do not block fluid flow through ports 153, 154. As will be described in more detail below, ball 155 axially reciprocates within cavity 152 in response to the axial reciprocation of pins 143, 144.
Cage 151 includes a first annular valve seat 151a at the intersection of port 154 and cavity 152 and a second annular valve seat 151b at the intersection of port 156 and cavity 152. Ball 155 reciprocates axially into and out of sealing engagement with seats 151a, 151b. Seats 151a, 151b are axially spaced such that when ball 155 engages seat 151a (
Referring still to
Shuttle valve 160 also includes a first hydraulic fluid inlet port 171, a second hydraulic fluid inlet port 172, a hydraulic fluid inlet-outlet port 173, and a hydraulic fluid inlet-outlet port 174. Inlet port 171 extends between passage 134 and first chamber 161, second inlet port 172 extends between passage 135 and second chamber 162, first port 173 extends from first chamber 161 to passage 136, and second port 174 extends from second chamber 162 to passage 137. Passage 134 and first section 161a of chamber 161 are always in fluid communication via inlet port 171, and passage 135 and first section 162a of chamber 162 are always in fluid communication via inlet port 172. However, pistons 163, 164 selectively control fluid communication between sections 161a, 162a and passages 136, 137, respectively, via ports 173, 174 respectively.
Diverter 165 is axially positioned between chambers 161, 162 and corresponding pistons 163, 164. Diverter 165 has a first end 165a facing chamber 161, a second end 165b facing chamber 162, a throughbore 167 extending axially between ends 165a, 165b, and a hydraulic fluid return port 168 in fluid communication with throughbore 167 and hydraulic fluid return passage 114. A first annular valve seat 169a is disposed about throughbore 167 at end 165a and a second annular valve seat 169b is disposed about throughbore 167 at end 165b. Connection rod 166 extends axially through throughbore 167, but does not engage diverter 165. Namely, rod 166 has an outer diameter that is less than the diameter of throughbore 167. Thus, rod 166 does not prevent fluid communication between throughbore 167 and port 168.
Pistons 163, 164 reciprocate axially into and out of sealing engagement with seats 169a, 169b, respectively. Rod 166 has an axial length greater than the axial length of diverter 165. Thus, when piston 163 sealingly engages seat 169a, piston 164 is axially spaced from seat 169b; and when piston 164 sealingly engages seat 169b, piston 163 is axially spaced from seat 169a.
When piston 163 engages seat 169a as shown in
As previously described, distribution system 130 alternates the supply of pressurized hydraulic fluid from hydraulic pump 200 between sections 121b, 125b of fluid end pump 110 to axially reciprocate pistons 600, 600′ and pump well fluids to the surface via tubing 40. Referring first to
As pistons 600, 600′ move in the first direction, the volume of section 121b increases (as it fills with pressurized hydraulic fluid), and the volume of section 125b decreases. However, as the volume of section 125b decreases, the hydraulic fluid in section 125b flows through passage 137, port 174, section 162b, throughbore 167, port 168 and return passage 114 to compensator 350, thereby avoiding hydraulic lock of pistons 600, 600′ and allowing pistons 600, 600′ continue to move axially in the first direction until piston 600′ axially impacts end 142b of pushrod 142.
Referring now to
As pistons 600, 600′ move in the second direction, the volume of section 125b increases (as it fills with pressurized hydraulic fluid), and the volume of section 121b decreases. However, as the volume of section 121b decreases, the hydraulic fluid in section 121b flows through passage 136, port 173, section 161b of chamber 161, throughbore 167, port 168 and return passage 114 to compensator 350, thereby avoiding hydraulic lock of pistons 600, 600′. Pistons 600, 600′ continue to move axially in the second direction until piston 600 axially impacts pushrod 141 and the process repeats as previously described.
As previously described, ball 155 is moved axially between seats 151a, 151b by pins 143, 144. When ball 155 engages seat 151b, the pressurized hydraulic fluid in cavity 152 is supplied to section 161a of chamber 161, and when ball 155 engages seat 151a, the pressurized hydraulic fluid in cavity is supplied to section 162a of chamber 162. However, during the relatively short period of time when ball 155 is moving between seats 151a, 151b, pressurized hydraulic fluid in cavity 152 is provided to both sections 161a, 162a. This may result in the premature actuation of shuttle valve 160, which can negatively affect the operation of distribution system 130. Therefore, it is generally preferred that pistons 163, 164 do not move in the first direction until ball 155 is fully seated against seat 151a, and further, that pistons 163, 164 do not move in the second direction until ball 155 is fully seated against seat 151b. Accordingly, in this embodiment, a calibration member 190 is provided in shuttle valve 160 to prevent pistons 163, 164 from moving in the first direction before ball 155 is fully seated against seat 151a, and prevent pistons 163, 164 from moving in the second direction until ball 155 is fully seated against seat 151b. As will be described in more detail below, calibration member 190 varies the cross-sectional area of piston 163 exposed to pressurized hydraulic fluid in section 161a to prevent the premature actuation of shuttle valve 160.
Referring now to
Referring still to
In
Referring again to
In this embodiment, calibration member 190 and pistons 163, 164 are sized such that surface area A163-1 is greater than surface area A164-1. As a result, with shuttle valve 160 in the first position shown in
As shown in
Thus, area A164-2 is the same as area A164-1, however, area A163-2 is less than area A163-1 because diameter D191b is greater than diameter D191a. In this embodiment, calibration member 190 and pistons 163, 164 are sized such that area A163-2 is less than area A164-2. As a result, with shuttle valve 160 in the second position shown in
Referring now to
In this embodiment, both inlet valve 520 and outlet valve 560 are double poppet valves. Inlet valve 520 includes a seating assembly 521 disposed in bore 511 at end 510b, a retention assembly 530 disposed in bore 511 at end 510b, a primary poppet valve member 540, and a backup or secondary poppet valve member 550 telescopically coupled to primary poppet valve member 540. Retention assembly 521, seating assembly 530, and valve members 540, 550 are coaxially aligned with bore axis 513.
Seating assembly 521 includes a seating member 522 threaded into bore 511 at end 510b, an end cap 526, and a biasing member 529. Seating member 522 has a first end 522a proximal body end 510b, a second end 522b disposed in bore 511 opposite end 522a, and a central through passage 523 extending axially between ends 522a, 522b. In addition, the radially inner surface of seating member 522 includes an annular recess 524 proximal end 522a, a first annular shoulder 525a axially spaced from recess 524, and a second annular shoulder 525b axially spaced from shoulder 525a. First annular shoulder 525a is axially disposed between recess 524 and shoulder 525b. As will be described in more detail below, valve members 540, 550 move into and out of engagement with shoulders 525a, 525b, respectively, to transition between closed and opened positions. Thus, annular shoulders 525a, 525b may also be referred as valve seats 525a, 525b, respectively.
End cap 526 is disposed in passage 523 at end 522a and is maintained within passage 523 with a snap ring 527 that extends radially into retention member recess 524. As best shown in
Referring again to
Referring still to Figure and 5, retention assembly 530 includes a retention member 531 threaded into bore 511 at end 510a, an end cap 538, and a biasing member 539. Retention member 531 has a first end 531a disposed in bore 511 and a second end 531b flush with end 510a. In addition, retention member 531 includes a central through passage 532 extending axially between ends 531a, 531b, and an annular shoulder 533 axially positioned between ends 531, b in passage 532. End cap 538 is threaded into passage 532 at end 531b and closes off passage 532 and bore 511 at end 531b.
Secondary valve member 550 extends axially into passage 532. In particular, secondary valve member 550 slidingly engages retention member 531 between end 531a and shoulder 533, but is radially spaced from retention member 531 between shoulder 533 and end 531b. A retention ring 534 disposed about secondary valve member 550 is axially positioned between shoulder 533 and end 531b. A snap ring 535 disposed about secondary valve member 550 prevents retention ring 534 from sliding axially off of secondary valve member 550. Thus, biasing member 539 biases secondary valve member 550 axially towards end 510b and into engagement with valve seat 525b. In other words, biasing member 539 biases secondary valve member 550 to a “closed” position. Specifically, when secondary valve member 550 is seated in valve seat 525b, axial fluid flow through inlet valve 520 between inlet passage 111 and section 121a is restricted and/or prevented. Although biasing member 539 is a coil spring in this embodiment, in general, biasing member (e.g., biasing member 539) may comprise any suitable device for biasing the primary valve member (e.g., valve member 550) to the closed position.
Referring still to
Stem 551 of secondary valve member 550 extends axially into passage 532 and includes an annular recess in which snap ring 535 is seated. Secondary valve member 550 also includes a central counterbore 554 extending axially from end 550a through head 552 and into stem 551. Stem 541 of primary valve member 540 is slidingly received by counterbore 554. Further, head 542 of primary valve member 540 includes a cylindrical recess 546. Biasing member 529 is seated in recess 546, which restricts and/or prevents biasing member 529 from moving radially relative to valve head 542.
As previously described, during pumping operations, inlet valve 520 of upper valve assembly 500 controls the supply of well fluids 15 to section 121a. In particular, valve members 540, 550 are biased to closed positions engaging seats 525a, 525b, respectively, and valve heads 542, 552, are axially positioned between seats 525a, 525b, respectively, and section 121a. Thus, when the pressure in chamber 121a is equal to or greater than the pressure in passage 111, valves heads 542, 552 sealingly engage valve seats 525a, 525b, respectively, thereby restricting and/or preventing fluid flow between passage 111 and section 121a. However, as piston 600 begins to move axially downward within chamber 121, the volume of section 121a increases and the pressure therein decreases. As the pressure in section 121a drops below the pressure in passage 111, the pressure differential seeks to urge valves members 540, 550 axially downward and out of engagement with seats 525a, 525b, respectively. Biasing members 529, 539 bias valve members 540, 550, respectively, in the opposite axial direction and seek to maintain sealing engagement between biasing members valve heads 542, 552 and valve seats 525a, 525b, respectively. However, once the pressure in section 121a is sufficiently low (i.e., low enough that the pressure differential between section 121a and passage 111 is sufficient to overcome biasing member 529), valve member 540 unseats from seat 525a and compresses biasing member 529. Then, almost instantaneously, the combination of the relatively low pressure in section 121a and relatively high pressure of well fluids in passage 111 overcomes biasing member 539, valve member 550 unseats from seat 525b and compresses biasing member 539, thereby transitioning inlet valve 520 to an “opened” position allowing fluid communication between passage 111 and section 121a. Since the pressure in section 121a is less than the pressure of well fluids 15 in passage 111, well fluids 15 will flow through inlet valve 520 into section 121a from passage 111. In this embodiment, biasing members 529, 539 provide different biasing forces. In particular, biasing member 529 provides a lower biasing force than biasing member 539 (e.g., biasing member 529 is a lighter duty coil spring than biasing member 539).
After piston 600 reaches its axially innermost stroke end proximal distribution system 130 and begins to move axially upward within chamber 121, the volume of chamber 121a decreases and the pressure therein increases. Once the pressure in section 121a in conjunction with the biasing forces provided by biasing members 529, 539 are sufficient to overcome the pressure in passage 111, valve members 540, 550 move axially upward and seat against valve seats 525a, 525b, respectively, thereby transitioning back to the closed positions restricting and/or preventing fluid communication between section 121a and passage 111.
Referring still to
Seating member 561 is threaded into counterbore 512 at end 510b and has a first end 561a flush with body end 510b, a second end 561b disposed in counterbore 512 opposite end 561a, and a central through passage 562 extending axially between ends 561a, 561b. In addition, the radially inner surface of seating member 561 includes an annular shoulder 563 proximal end 561a. As will be described in more detail below, valve members 580, 590 move into and out of engagement with shoulder 563 and end 561b, respectively, to transition between closed and opened positions. Thus, annular shoulder 563 and seat member end 561b may also be referred as valve seats 563, 561b, respectively.
Valve member 580 is disposed in passage 562 and has a first end 580a and a second end 580b opposite end 580a. End 580a comprises a radially enlarged valve head 581 that mates with and sealingly engages valve seat 563. In this embodiment, valve head 581 includes a spherical sealing surface 582 that sealingly engages a mating spherical surface of valve seat 563. A biasing member 569 is axially compressed between valve members 580, 590. Thus, biasing member 569 biases primary valve member 580 axially away from valve member 590 and into engagement with valve seat 563. In other words, biasing member 569 biases primary valve member 580 to a “closed” position. Specifically, when primary valve member 580 is seated in valve seat 563, fluid communication between outlet passage 113 and section 121a is restricted and/or prevented. In this embodiment, biasing member 569 is seated in a cylindrical counterbore 583 extending axially from end 580b, thereby restricting and/or preventing biasing member 569 from moving radially relative to valve member 580. Although biasing member 569 is a coil spring in this embodiment, in general, biasing member (e.g., biasing member 569) may comprise any suitable device for biasing the primary valve member (e.g., valve member 580) to the closed position.
Referring still to
Valve member 590 is disposed in passage 562 and has a first end 590a and a second end 590b opposite end 590a. End 590a comprises a radially enlarged valve head 591 that mates with and sealingly engages valve seat 561b. In this embodiment, valve head 591 includes a spherical sealing surface 592 that sealingly engages a mating spherical surface of valve seat 561b. As previously described, biasing member 579 biases valve member 590 into sealing engagement with seat 561b. In addition, in this embodiment, end 590b comprises a cylindrical tip 593 that extends axially into biasing member 579, thereby restricting and/or preventing biasing member 579 and valve member 590 from moving radially relative to each other.
As previously described, during pumping operations, outlet valve 560 of upper valve assembly 500 controls the flow of well fluids 15 from section 121a into conduit 40. In particular, valve members 580, 590 are biased to closed positions engaging seats 563, 561b, respectively, and valve seats 563, 561b are axially positioned between valve heads 581, 591, respectively, and section 121a. Thus, when the pressure in chamber 121a is less than the pressure in passage 113 and coupling 45, valves heads 581, 591 sealingly engage valve seats 563, 561b, respectively, thereby restricting and/or preventing fluid flow between coupling 45 and section 121a. However, as piston 600 begins to move axially upward within chamber 121, the volume of section 121a decreases and the pressure therein increases. As the pressure in section 121a increases above the pressure in passage 112 and coupling 45, the pressure differential seeks to urge valves members 580, 590 axially upward and out of engagement with seats 563, 561b, respectively. Biasing members 569, 579 bias valve members 580, 590, respectively, in the opposite axial direction and seek to maintain sealing engagement between biasing members valve heads 581, 591 and valve seats 563, 561b, respectively. However, once the pressure in section 121a is sufficiently high (i.e., high enough that the pressure differential between section 121a and passage 112 is sufficient to overcome biasing members 569), valve member 580 will unseat from seat 563 and compresses biasing member 569. Then, almost instantaneously, the combination of the relatively high pressure in section 121a and relatively lower pressure in passage 112 overcome biasing member 579, valve member 590 unseats from seat 561b, thereby transitioning outlet valve 560 to an “opened” position allowing fluid communication between passage 112 and section 121a. Since the pressure in section 121a is greater than the pressure of well fluids 15 in passage 112, well fluids 15 will flow through outlet valve 560 from section 121a into passage 112, coupling 45, and conduit 40. In this embodiment, biasing members 569, 579 provide different biasing forces. In particular, biasing member 569 provides a lower biasing force than biasing member 579 (e.g., biasing member 569 is a lighter duty coil spring than biasing member 579).
After piston 600 reaches its axially outermost stroke end distal distribution system 130 and begins to move axially downward within chamber 121, the volume of chamber 121a increases and the pressure therein decreases. Once the pressure in coupling 45 in conjunction with the biasing forces provided by biasing members 569, 579 are sufficient to overcome the pressure in section 121a, valve members 580, 590 move axially downward and seat against valve seats 563, 561b, respectively, thereby transitioning back to the closed positions restricting and/or preventing fluid communication between section 121a and coupling 45.
Referring now to
As previously described, during pumping operations, inlet valve 520 of lower valve assembly 500′ controls the supply of well fluids 15 to section 125a. In particular, valve members 540, 550 are biased to closed positions engaging seats 525a, 525b, respectively, and valve heads 542, 552, are axially positioned between seats 525a, 525b, respectively, and section 121a. Thus, when the pressure in chamber 125a is equal to or greater than the pressure in well fluids flow passage 116, valves heads 542, 552 sealingly engage valve seats 525a, 525b, respectively, thereby restricting and/or preventing fluid flow between well fluids flow passage 116 and section 125a. However, as piston 600′ begins to move axially upward within chamber 125, the volume of section 125a increases and the pressure therein decreases. As the pressure in section 125a drops below the pressure in well fluids flow passage 116, the pressure differential seeks to urge valves members 540, 550 axially downward and out of engagement with seats 525a, 525b, respectively. Biasing members 529, 539 bias valve members 540, 550, respectively, in the opposite axial direction and seek to maintain sealing engagement between biasing members valve heads 542, 552 and valve seats 525a, 525b, respectively. However, once the pressure in section 125a is sufficiently low (i.e., low enough that the pressure differential between section 125a and well fluids flow passage 116 is sufficient to overcome biasing members 529, 539), valve members 540, 550 will unseat from seats 525a, 525b, respectively, thereby transitioning inlet valve 520 of lower valve assembly 500′ to an “opened” position allowing fluid communication between well fluids flow passage 116 and section 125a. Since the pressure in section 125a is less than the pressure of well fluids 15 in well fluids flow passage 116, well fluids 15 will flow through inlet valve 520 into section 125a from well fluids flow passage 116. In this embodiment, biasing members 529, 539 provide different biasing forces. In particular, biasing member 529 provides a lower biasing force than biasing member 539 (e.g., biasing member 529 is a lighter duty coil spring than biasing member 539). Thus, valve member 540 of lower valve assembly 500′ will unseat just before valve member 550 of lower valve assembly 500′.
After piston 600′ reaches its axially innermost stroke end proximal distribution system 130 and begins to move axially downward within chamber 125, the volume of chamber 125a decreases and the pressure therein increases. Once the pressure in section 125a in conjunction with the biasing forces provided by biasing members 529, 539 are sufficient to overcome the pressure in well fluids flow passage 116, valve members 540, 550 move axially upward and seat against valve seats 525a, 525b, respectively, thereby transitioning back to the closed positions restricting and/or preventing fluid communication between section 125a and well fluids flow passage 116.
Referring still to
After piston 600′ reaches its axially outermost stroke end distal distribution system 130 and begins to move axially upward within chamber 125, the volume of chamber 125a increases and the pressure therein decreases. Once the pressure in passage 112 in conjunction with the biasing forces provided by biasing members 569, 579 are sufficient to overcome the pressure in section 125a, valve members 580, 590 move axially downward and seat against valve seats 563, 561b, respectively, thereby transitioning back to the closed positions restricting and/or preventing fluid communication between section 125a and passage 112.
In the manner described, inlet valve 520 and outlet valve 560 of upper valve assembly 500 control the flow of well fluids 15 into and out of section 121a, and inlet valve 520 and outlet valve 560 of lower valve assembly 500′ control the flow of well fluids 15 into and out of section 125a. Each valve 520, 560 includes two poppet valve members adapted to move into and out of engagement with mating valve seats. Namely, inlet valve 520 includes poppet valve members 540, 550, and outlet valve 560 includes poppet valve members 580, 590. Valve members 540, 550 are capable of operating independent of one another. Thus, valve member 540 may seat against valve seat 525a even if valve member 550 is not seated against valve seat 525b, and vice versa. Likewise, valve members 580, 590 are capable of operating independent of one another. Thus, valve member 580 may seat against valve seat 563 even if valve member 590 is not seated against valve seat 561b, and vice versa. Inclusion of multiple, serial, operationally independent valve members 540, 550 in inlet valve 520 offers the potential to enhance the reliability and sealing of inlet valve 520 in harsh downhole conditions. For example, even if valve member 540 gets stuck in the opened position (e.g., solids get jammed between valve member 540 and seat 525a), valve member 550 can still sealingly engage valve seat 525b, thereby closing inlet valve 520. Likewise, inclusion of multiple, serial, operationally independent valve members 580, 590 in outlet valve 560 offers the potential to enhance the reliability and sealing of inlet valve 560 in harsh downhole conditions. For example, even if valve member 590 gets stuck in the opened position (e.g., solids get jammed between valve member 590 and seat 561b), valve member 580 can still sealingly engage valve seat 563, thereby closing outlet valve 560.
Referring again to
Referring now to
Referring still to
A plurality of annular seals 604, 605 are mounted to outer surface 602 of piston housing 601 and slidingly engage pump housing 120. Each seal 604, 605 forms an annular static seal with piston housing 601 and an annular dynamic seal with pump housing 120, thereby restricting and/or preventing the flow of fluids (well fluids and hydraulic fluid) between piston 600 and pump housing 120. Select seals 604, 605 are axially positioned on opposite sides of recess 614 and drain ports 615. More specifically, a first plurality of seals 604, collectively identified with reference numeral “603a,” are axially positioned between end 601a and drain ports 615, while a second plurality of seals 604, 605, collectively identified with reference numeral “603b,” are axially positioned between end 601b and drain ports 615. Thus, any well fluids in section 121a that pass first plurality of seals 603a drain into ports 615 before reaching second plurality of seals 603b, and any hydraulic fluid in section 121b that passes second plurality of seals 603b drain into recess 614 and ports 615 before reaching first plurality of seals 603a. Since first plurality of seals 603a see well fluids, they may also be referred to as “well fluid seals,” and since second plurality of seals 603b see hydraulic fluid, they may also be referred to as “hydraulic fluid seals.” Although seals 604, 605 can seal against both gases and liquids, in this embodiment, seals 604 are primarily designed to seal against liquids, whereas seals 605 are primarily designed to seal against gases.
Referring still to
In this embodiment, decompression valve 620 includes a radially outer valve body or housing 630, a valve member 640 moveably disposed in valve body 630, an elongate guide 650 disposed in valve body 630, and a plurality of biasing members 660a, 660b, 660c, 660d disposed about guide 650 within valve body 630. Decompression valve 620 is maintained within piston housing 601 by an end cap 670 coaxially disposed in throughbore 611 at end 601a and secured to piston housing 601 against shoulder 612 with a snap ring 671.
End cap 670 has a first or upper end 670a, a second or lower end 670b, a counterbore 672 extending axially from end 670b, and a throughbore 673 extending axially from end 670a to counterbore 672. As best shown in
Referring still to
Outer surface 631 includes an annular shoulder 632a positioned proximal end 630b, thereby dividing outer surface 631 into a first cylindrical section 632b extending axially from end 630a to shoulder 632a and a second cylindrical section 632c extending axially from end 630b to shoulder 632a. Flow passages 636 are axially positioned adjacent shoulder 632a between end 630a and shoulder 632a. Second cylindrical section 632c slidingly engages inner surface 610, however, first cylindrical section 632b is radially spaced from inner surface 610 of piston housing 601, thereby defining an annular space or annulus 633 therebetween.
Valve body 630 is disposed in throughbore 611 with end 630b axially abutting and seated against shoulder 613. End 630a extends into counterbore 672 of end cap 670. However, end 630a is axially spaced from end cap 670 and first cylindrical section 632b is radially spaced from end cap 670, resulting in an annular flow passage 639 that extends radially along end 630a and axially first cylindrical section 632b to annulus 633.
End 180a of rod 180 is positioned in counterbore 635 and bore 637, and thus, throughbore 181 is in fluid communication with radial flow passages 636. End 180a is secured within piston 600 and counterbore 635 with a locking ring 638 seated in counterbore 635. Ring 638 is wedged between piston housing 601 and rod 180, thereby urging ring 638 into positive engagement with mating annular recesses provided on the outer surface of rod 180.
Referring still to
As best shown in
Referring again to
As previously described, decompression valve 620 is biased closed with shoulder 646 of valve member 640 engaging valve seat 674 of end cap 670. With decompression valve 620 in the closed position (
As previously described, piston 600′ is identical to piston 600 with the exception that piston 600′ is coupled to end 180b of rod 180, whereas piston 600 is coupled to end 180a of rod 180, and piston 600 axially engages first pushrod 141 and upper valve assembly 500 within chamber 121, whereas piston 600′ axially engages second pushrod 142 and lower valve assembly 500′ within chamber 125. Thus, decompression valve 620 of piston 600′ has a closed position restricting and/or preventing fluid flow between section 125a and throughbore 181, and an open position allowing fluid flow between section 125a and throughbore 181. In addition, decompression valve 620 of piston 600′ can be transitioned from the closed position to the open position in two different manners: (1) by physically pushing valve member 640 axially toward valve body 630 to unseat shoulder 646 from valve seat 674; and (2) by a sufficient pressure differential between section 121a and flow passage 639. Regarding (1), pushrod 141 of distribution system 130 is specifically sized such that as piston 600′ moves axially in the second direction to the axially outermost position relative to distribution system 130, end 640a of valve member 640 of piston 600′ engages lower valve assembly 500′ and is pushed into valve body 630 a sufficient axial distance to unseat shoulder 646 from valve seat 674. Regarding (2), the axially opposed surfaces of end cap 670 and valve member 640, and the axially opposed surfaces of valve member 640 and valve body 630, are sized such that a sufficient pressure differential between flow passage 639 (relatively high pressure) and well fluids section 121a (relatively low pressure, which also results in a relatively low pressure within counterbores 634, 642 between valve member 640 and valve body 630) overcomes the biasing force generated by biasing members 660a, 660b, 660c, 660d, thereby moving valve member 640a sufficient axial distance relative to valve body 630 to unseat shoulder 646 from valve seat 674. Recess 614 and drain ports 615 of piston housing 601 of piston 600′ are designed and positioned to drain any well fluids that flow from section 125a between piston 600′ and pump housing 120, thereby reducing the potential for such well fluids to undesirably contaminate hydraulic fluid in section 125b.
Referring again to
The well fluids pumped by fluid end pump 110 may contain gas, especially when pump 100 is used to dewater gas wells. Without being limited by this or any particular theory, gases are generally compressible, whereas water and hydraulic fluid are generally incompressible. The ability to decompress the well fluids in section 121a, 125a being pressurized to the other section 125a, 121a, respectively, offers the potential to improve the operability of fluid end pump 110 when pumping well fluids containing variable amounts of gas. In particular, decompression valves 620 stabilize the response of distribution system 130 by allowing decompression of the gas in the well fluids to avoid the restitution effect, which can abruptly change the direction of movement of the pistons 600, thereby causing the premature disengagement of the pushrod 141, 142 and potential unseating of ball 155. Decompression valves 620 also reduce the axial forces applied to pushrods 141, 142, which may enhance the durability and operating lifetime of distribution system 130. In particular, decompression valves 620 reduce the well fluids pressure in sections 121a, 125a during pressurization, which in turn reduces the hydraulic oil pressure in sections 121b, 125b since the hydraulic oil pressure in sections 121b, 125b is a function of the resistance to movement provided by well fluids pressure in sections 121a, 125a.
As previously described, pistons 600, 600′ are disposed within chambers 121, 125, respectively, and divide chambers 121, 125 into well fluids sections 121a, 125a and hydraulic fluid sections 121b, 125b. Thus, pistons 600, 600′ separate hydraulic fluid in sections 121b, 125b, respectively, from well fluids in sections 121a, 125a, respectively. In addition, the well fluids pumped by fluid end pump 110 may contain gas. Since gases are generally compressible, unlike hydraulic fluid, and water does not have the desired lubricating properties of hydraulic fluid, pistons 600, 600′ are designed to restrict and/or prevent the well fluids in sections 121b, 125b, respectively, from contaminating the hydraulic fluid in sections 121a, 125a, respectively. In particular, seals 604, 605 provide annular seals between piston housings 601 and pump housing 120. In addition, embodiments of pistons 600, 600′ described herein include annular recess 614 and drain ports 615, which are designed and positioned to drain any well fluids (and gases contained therein) that seek to flow from section 121a, 125a into section 121b, 125b, respectively. Thus, any well fluids that pass well fluid seals 603a drain through recess 614 and ports 615 into flow passage 639 of the corresponding piston 600, 600′, are subsequently swept away into the well fluids section 121a, 125a of the other piston 600, 600′ upon decompression (i.e., when decompression valves 620 are transitioned open and relatively high pressure well fluids in section 121a, 125a are decompressed into the relatively low pressure well fluids in the other section 121a, 125a, respectively), and are eventually pumped to the surface along with the other well fluids in that section 121a, 125a.
Referring now to
A tubular well fluids conduit 205 extends coaxially through hydraulic pump 200 and is in fluid communication with flow passage 116 of distributor 115. As will be described in more detail below, conduit 205 supplies well fluids 15 from separator 400 to fluid end pump 110 via distributor flow passage 116. Although conduit 205 extends through hydraulic pump 200, it is not in fluid communication with any of chambers 220, 230, 240.
Referring now to
Passage 214 is in fluid communication with hydraulic fluid passage 113 of fluid end pump 110 previously described. Thus, hydraulic pump 200 supplies pressurized hydraulic fluid to distribution system 130 via branches 215, 216 and passages 214, 113. As previously described, hydraulic fluid return passage 114 allows hydraulic fluid from distribution system 130 to return to upper chamber 220, which is in fluid communication with compensator 350. End caps 212, 213 include throughbores 218, 219, respectively, through which conduit 205 extends.
Referring still to
Guide member 251 axially abuts end cap 212 and is fixably secured thereto with bolts (not visible in the cross-section shown in
Biasing sleeve 261 has a first or upper end 261a disposed in counterbore 254, a second end 261b opposite end 261a, and a radially inner surface including an annular shoulder 262 between ends 261a, 261b and a frustoconical seat 263 at end 261b. Biasing member 260 axially abuts annular shoulder 262 and guide member 251, and swivel plate 265 is pivotally seated in seat 263.
Each piston 255 is disposed at the same radial distance from axis 105 and has a first end 255a disposed in one bore 253, a second end 255b axially positioned between swivel plate 265 and wobble plate 270, and a throughbore 256 extending axially between ends 255a, 255b. Throughbore 256 of each piston 255 is in fluid communication with its corresponding bore 253. In this embodiment, end 255b of each piston 255 comprises a spherical head 257.
Referring still to
It should be appreciated that swivel plate 265 is disposed about conduit 205 but radially spaced from conduit 205 by a radial distance that provides sufficient clearance therebetween as swivel plate 265 pivots relative to biasing sleeve 261. Likewise, each bore 269 in swivel plate 265 has a diameter greater than the outside diameter of the portion of piston 255 extending therethrough to provide sufficient clearance therebetween as swivel plate 265 pivots relative to that piston 255.
Referring now to
As best shown in
Referring briefly to
Referring now to
As wobble plate 270 rotates, the axial distance from each piston guide bore 253 to wobble plate end face 271 cyclically varies. For example, the axial distance from a given guide bore 253 and end face 271 is maximum when the “thin” portion of wobble plate 270 is axially opposed that guide bore 253, and the axial distance from a given guide bore 253 and end face 271 is minimum when the “thick” portion of wobble plate 270 is axially opposed that guide bore 253. However, pistons 255 move axially back and forth within bores 253 to maintain piston head 257 axially adjacent end face 271. Specifically, biasing member 260 biases biasing sleeve 261 axially into swivel plate 265, which in turn, biases retention rings 290 and corresponding piston heads 257 against end face 271. Sliding engagement of swivel plate and bias sleeve seat 263 allows simultaneous axial biasing of swivel plate 265 and pivoting of swivel plate 265 relative to biasing sleeve 261. It should also be appreciated that engagement of each spherical piston head 257 with a corresponding mating frustoconical seat in both retention ring 290 and shoe 295 enables ring 290 and shoe 295 to slidingly engage head 257 and pivot about head 257 while maintaining contact with head 257 and plates 265, 270, respectively.
As wobble plate 270 rotates, pistons 255 reciprocate axially within guide bores 253 and slot 272 cyclically moves into and out of fluid communication with bore 256 of each piston 255. In particular, wobble plate 270 is rotated such that bore 256 of each piston 255 first comes into fluid communication with slot 272 at end 272a and moves out of fluid communication with slot 272 at end 272b. Thus, bore 256 of each piston 255 is in fluid communication with slot 272 as corresponding piston head 257 moves axially downward and away from guide member 251 as it is biased against end face 271. Accordingly, bore 256 of each piston 255 is in fluid communication with slot 272 as piston 255 telescopically extends axially from its corresponding bore 253. As previously described, check valve 217 in each branch 215 only allows one-way fluid communication from bore 253 to corresponding branch 215. Thus, as each piston 255 extends from its corresponding guide bore 253, the fluid pressure within associated bores 253, 256 decreases and hydraulic fluid within chamber 220 flows through slot 272 and fills bores 253, 256. As will be described in more detail below, compensator 350 maintains hydraulic fluid in chambers 220, 230, 240 at a fluid pressure sufficient to push hydraulic fluid into pistons 255 when piston bores 256 are in fluid communication with chambers 220, 230, 240 via slot 272.
Conversely, once each piston 256 moves out of fluid communication with slot 272, corresponding piston head 257 moves axially upward and toward guide member 251. Accordingly, bore 256 of each piston 255 is isolated from (i.e., not in fluid communication with) slot 272 as piston 255 is telescopically pushed axially into its corresponding bore 253. As each piston 255 is axially pushed further into its corresponding guide bore 253, the hydraulic fluid in associated bores 253, 256 is compressed. As previously described, check valve 217 in each branch 215 only allows one-way fluid communication from bore 253 to corresponding branch 215. Thus, when the hydraulic fluid in bores 253, 256 is sufficiently compressed (i.e., the pressure differential across check valve 217 exceeds the cracking pressure of check valve 217), corresponding check valve 217 will open and allow the pressurized hydraulic fluid in bores 253, 256 to flow into associated branch 215 and passage 214.
Referring again to
Lower pump assembly 280 functions in the same manner as upper pump assembly 280 to supply pressurized hydraulic fluid to distribution system 130. However, each guide bore 253 of guide member 251 of lower pump assembly 280 is in fluid communication with one branch 216 in lower end cap 213. Thus, lower pump assembly 280 provides pressurized hydraulic fluid to distribution system 130 via branches 216 and passages 214, 113. In particular, driveshaft 298 drives the rotation of lower wobble plate 270. As lower wobble plate 270 rotates, pistons 255 of lower pump assembly 280 reciprocate axially within guide bores 253 and slot 272 in lower wobble plate 270 cyclically moves into and out of fluid communication with bore 256 of each piston 255. In particular, lower wobble plate 270 is rotated such that bore 256 of each piston 255 first comes into fluid communication with slot 272 at end 272a (generally aligned with point 271a of lower wobble plate 270) and moves out of fluid communication with sot 272 at end 272b (generally aligned with point 271b of lower wobble plate 270). Thus, bore 256 of each piston 255 is in fluid communication with slot 272 as corresponding piston head 257 moves axially upward and away from guide member 251 as it is biased against end face 271 of lower wobble plate 270. Accordingly, bore 256 of each piston 255 is in fluid communication with slot 272 of lower wobble plate as piston 255 telescopically extends axially from its corresponding bore 253. Check valve 217 in each branch 216 only allows one-way fluid communication from bore 253 to corresponding branch 216. Thus, as each piston 255 extends from its corresponding guide bore 253, the fluid pressure within associated bores 253, 256 decreases and hydraulic fluid within chamber 230 flows through slot 272 in lower wobble plate 270 and fills bores 253, 256. Conversely, once each piston 256 of lower pump assembly 280 moves out of fluid communication with slot 272 in lower wobble plate 270, corresponding piston head 257 moves axially downward and toward guide member 251. Accordingly, bore 256 of each piston 255 in lower pump assembly 280 is isolated from (i.e., not in fluid communication with) slot 272 of lower wobble plate as piston 255 is telescopically pushed axially into its corresponding bore 253. As each piston 255 of lower pump assembly 280 is axially pushed further into its corresponding guide bore 253, the hydraulic fluid in associated bores 253, 256 is compressed. As previously described, check valve 217 in each branch 216 only allows one-way fluid communication from bore 253 to corresponding branch 216. Thus, when the hydraulic fluid in bores 253, 256 is sufficiently compressed (i.e., the pressure differential across check valve 217 exceeds the cracking pressure of check valve 217), corresponding check valve 217 will open and allow the pressurized hydraulic fluid in bores 253, 256 to flow into associated branch 216 and passage 214.
In the manner described, each piston 255 of upper pump assembly 250 and lower pump assembly 280 axially reciprocates within its corresponding guide bore 253, piston bores 256 move into and out of fluid communication with slots 272, and pressurized hydraulic fluid is supplied to distribution system 130 via branches 215, 216 and passages 214, 113. Although only one piston 255 is shown in each pump assembly 250, 280, however, as previously described, in this embodiment, each pump assembly 250, 280 includes three identical, uniformly circumferentially-spaced pistons 255 that function in the same manner. Thus, at any given time during rotation of wobbles plate 270, at least one piston 255 of each assembly 250, 280 is being filled with hydraulic fluid and at least one piston 255 of each assembly 250, 280 is providing pressurized hydraulic fluid to distribution system 130. Accordingly, hydraulic pump 200 continuously provides pressurized hydraulic fluid to distribution system 130 to drive fluid end pump 110.
Referring again to
Referring still to
Referring now to
A controller (not shown), which may be disposed at the surface 11 or downhole, controls the speed of motor 320 in response to sensed pressure at the bottom of wellbore 20. Wires disposed in or coupled to conduit 40 provide electricity to power the operation of motor 300.
In general, motor 300 may comprises any suitable type of electric motor that converts electrical energy provided by wires in or coupled to conduit 40 into mechanical energy in the form of rotational torque and rotation of driveshaft 320. Examples of suitable electric motors include, without limitation, DC motors, AC motors, universal motors, brushed motors, permanent magnet motors, or combinations thereof. Due to the potentially high depth applications of deliquification pump 100 (e.g., depths in excess of 10,000 ft.), electric motor 300 is preferably capable of withstanding the relatively high temperatures experienced at such depths. In this embodiment, electric motor 300 is a permanent magnet motor. In addition, in this embodiment, motor housing 310 is filled with hydraulic fluid that can flow to and from hydraulic pump 200 and compensator 350. The hydraulic fluid facilitates heat transfer away from electric motor 300 and lubricates bearings 330. In particular, hydraulic fluid is continuously circulated between hydraulic pump 200 and distribution system 130 except during the inversion phase when pistons 600, 600′ are stationary (i.e., when pistons 600, 600′ are in the process of changing directions). During the inversion phase, the return of hydraulic fluid from distribution system 130 to hydraulic pump 200 temporarily ceases. However, pressurized hydraulic fluid from hydraulic pump 200 is still necessary to fully transition shuttle valve 160 in distribution system 130. Therefore, during the inversion phase, compensator 350 supplies hydraulic fluid to hydraulic pump 200 through motor 300. The hydraulic fluid supplied by compensator 350 to pump 200 during the inversion is returned from hydraulic pump 200 to compensator 350 through electric motor 300 between inversion phases. In this manner, hydraulic fluid is circulated between hydraulic pump 200 and compensator 350 through electric motor 300. In other embodiments, the electric motor (e.g., motor 300) may include heat dissipation fins extending radially from the motor housing (e.g., housing 310) to enhance the transfer of thermal energy from the electric motor to the surrounding environment.
Referring now to
Housing 351 includes an elongate tubular section 352, a first or upper end cap 353 closing off tubular section 352 at end 350a and coupling compensator 350 to motor 300, and a second or lower end cap 354 closing off tubular section 352 at end 350b. Section 352 and end caps 353, 354 define an internal chamber 360 within housing 351. Upper end cap 353 includes an axial throughbore 355 and a hydraulic fluid port 356, and lower end cap 354 includes a throughbore 357 and an annular shoulder 358. The upper end of throughbore 355 receives the lower end of conduit 205 (
Piston 370 is disposed in chamber 360 about conduit 395. In this embodiment, piston 370 includes a piston body 371 extending radially from conduit 395 to housing 351 and a tubular member 372 extending axially from piston body 371 toward end 350b. Piston body 371 slidingly engages both conduit 395 and housing 351, and divides chamber 360 into a first or upper chamber section 360a extending axially from upper end cap 353 to piston 370 and a second or lower chamber section 360b extending axially from piston 370 to lower end cap 354. In this embodiment, piston body 371 includes a plurality of axially spaced radially inner annular seals 373 that sealingly engage conduit 205, and a plurality of axially spaced radially outer annular seals 374 that sealingly engage housing tubular section 352. Seals 373, 374 restrict and/or prevent fluid communication between chamber sections 360a, 360b.
Referring still to
Chamber section 360a is filled with hydraulic fluid and chamber section 360b is filled with well fluids 15 from separator 400 via throughbore 357 and ports 392. Thus, as piston 370 moves axially within chamber 360 and the volume of section 360b changes, well fluids 15 are free to move into and out of section 360b via ports 358. The remainder of well fluids 15 output from separator 400 pass through bores 357, 391, conduit 395, bore 355, and conduit 205 to fluid end pump 110.
Tubular member 372 is disposed about biasing assembly 380 and defines a minimum axial distance between piston body 371 and lower end cap 354, thereby defining a maximum volume of chamber section 360a. In general, piston 370 is generally free to move axially within chamber 360; when piston 370 moves axially toward end cap 353, the volume of section 360a decreases and the volume of section 360b increases, and when piston 370 moves axially toward end cap 354, the volume of section 360a increases and the volume of section 360b decreases. However, tubular member 372 limits the axial movement of piston 370 toward end cap 354. Specifically, once tubular member 372 axially abuts end cap 354, piston 370 is prevented from moving axially downward.
Referring still to
Piston 370 is a free floating balance piston that moves in response to differences between the axial force applied by the hydraulic fluid pressure in section 360a, and the axial forces applied by biasing assembly 380 and well fluids pressure in section 360b. Specifically, piston 370 will move axially within chamber 360 until these axial forces are balanced. The hydraulic fluid in chamber section 360a is in fluid communication with motor housing 310 via end cap port 356, and is in fluid communication with hydraulic pump chambers 220, 230, 240 via clearances between pump housing end cap 213 and driveshaft shaft 298. Accordingly, if the volume, and associated pressure, of hydraulic fluid in pump 200, motor 300, and/or compensator 350 increases, it can be accommodated by compensator 350. Conversely, if the volume, and associated pressure, of hydraulic fluid in pump 200, motor 300, and/or compensator decreases (e.g., if any hydraulic fluid is lost due to seal leaks etc.), it can be replenished by hydraulic fluid from compensator 350.
As previously described, piston 370 moves axially within chamber 360 in response to differences between (a) the axial force applied by the hydraulic fluid pressure in section 360a, and (b) the sum of the axial force applied by biasing assembly 380 and the axial force applied by the well fluids pressure in section 360b. Thus, pressure of the hydraulic fluid in section 360a is equal to the pressure of well fluids in section 360a plus the pressure exerted by piston 370 on the hydraulic fluid in section 360a due to the axial force exerted by biasing assembly 380. LVP 100 is designed and configured such that springs 381 are in compression between piston 370 and end cap 354 and exert a positive pressure of about 3.0 bars on the hydraulic fluid in section 360a (via piston 370) above and beyond the pressure of the well fluids in section 360b. Section 360a is in fluid communication with chambers 220, 230, 240 of hydraulic pump 200, and thus, the hydraulic fluid in chambers 220, 230, 240 is also maintained at a positive pressure of about 3.0 bars above and beyond the pressure of well fluids in section 360b. Maintenance of a positive pressure of 3.0 bars on the hydraulic fluid in section 360a and chambers 220, 230, 240, regardless of the well fluids pressure, allows compensator 350 to push hydraulic fluid into bores 256, 253 when bores 256 are in fluid communication with chambers 220, 230, 240 via slots 272. It should also be appreciated that maintenance of the hydraulic fluid at a positive pressure above and beyond the pressure of the well fluids reduces the risk of well fluids in sections 121a, 125a penetrating into hydraulic fluid in sections 121b, 125b.
Referring now to
Referring now to
Fluid end pump 110 is driven by hydraulic pump 200, and hydraulic pump 200 is driven by electric motor 300. Conductors within or coupled to conduit 40 provide electrical power downhole to motor 300, which powers the rotation of motor driveshaft 320, hydraulic driveshaft 298, and wobble plates 270. As plates 270 rotate, hydraulic fluid in pump chambers 220, 230 is cyclically supplied to pistons 255 via slots 272, compressed in pistons 255, and then passed to distribution system 130 of fluid end pump 110 via branches 215, 216 and passages 214, 113. Hydraulic fluid distribution system 130 alternates the supply of pressurized hydraulic fluid to chamber sections 121b, 125b, thereby driving the reciprocation of fluid end pump pistons 600, 600′. Use of hydraulic pump 200 in conjunction with fluid end pump 110 offers the potential to generate the relatively high fluid pressures necessary to force or eject relatively low volumes of well fluids 15 to the surface 11. In particular, hydraulic pump 200 converts mechanical energy (rotational speed and torque) into hydraulic energy (reciprocating pressure and flow), and is particularly deigned to generate relatively high pressures at relatively low flowrates and at relatively high efficiencies. The addition of fluid end pump 110 allows for an isolated closed loop hydraulic pump system while limiting wellbore fluid exposure to fluid end pump 110. This offers the potential for improved durability and reduced wear. The fluid end pump only has minor hydraulic losses and for the most part is a direct relationship to the pressure output of the hydraulic system. In addition, the variable speed output capability of the system allows for variable pressure and flow output of the fluid end pump.
In general, the various parts and components of deliquification pump 100 may be fabricated from any suitable material(s) including, without limitation, metals and metal alloys (e.g., aluminum, steel, inconel, etc.), non-metals (e.g., polymers, rubbers, ceramics, etc.), composites (e.g., carbon fiber and epoxy matrix composites, etc.), or combinations thereof. However, the components of pump 100 are preferably made from durable, corrosion resistant materials suitable for use in harsh downhole conditions such steel. Although deliquification pump 100 is described in the context of deliquifying gas producing wells, it should be appreciated that embodiments of deliquification pump 100 described herein may also be used in oil wells. Further, although fluid end pump 110, pistons 600, 600′ of pump 110, and distribution system 130 are described within the context of deliquification pump 100 for removing fluids from a subterranean well, it should be appreciated that embodiments of fluid end pump 110, pistons 600, 600′, distribution system 130, or combinations thereof can be used in other applications or pumping devices.
While preferred embodiments have been shown and described, modifications thereof can be made by one skilled in the art without departing from the scope or teachings herein. The embodiments described herein are exemplary only and are not limiting. Many variations and modifications of the systems, apparatus, and processes described herein are possible and are within the scope of the invention. For example, the relative dimensions of various parts, the materials from which the various parts are made, and other parameters can be varied. Accordingly, the scope of protection is not limited to the embodiments described herein, but is only limited by the claims that follow, the scope of which shall include all equivalents of the subject matter of the claims. Unless expressly stated otherwise, the steps in a method claim may be performed in any order. The recitation of identifiers such as (a), (b), (c) or (1), (2), (3) before steps in a method claim are not intended to and do not specify a particular order to the steps, but rather are used to simplify subsequent reference to such steps.
This application claims benefit of U.S. provisional patent application Ser. No. 61/980,107 filed Apr. 16, 2014, and entitled “Reciprocating Pumps for Downhole Deliquification Systems and Fluid Distribution Systems for Actuating Reciprocating Pumps,” which is hereby incorporated herein by reference in its entirety.
Number | Date | Country | |
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61980107 | Apr 2014 | US |