Patent Grant
11428083
This disclosure relates to pumping hydrocarbon fluids from a well and, more particularly, pumping hydrocarbon fluids from two wells with a single pumping system.
Sucker rod pumping systems are common artificial lift systems for oil and gas wells and currently are widely utilized to maintain production of wells to their ultimate recovery. Typically, a single surface pumping unit is required for each well with a dedicated prime mover and sets of counter weights to provide the required counter balance effect. Such pumping units represent large capital investments and require large amounts of power.
This disclosure describes implementations of a hydrocarbon pumping system that is operable to pump hydrocarbon fluids from two wells simultaneously or substantially simultaneously. In some aspects, example implementations of a hydrocarbon pumping system includes a pumping jack system (e.g., a sucker rod pumping system) that is self-balancing through two separate horsehead assemblies. In some aspects, each horsehead acts as a counterbalance weight to the other of the horseheads.
In an example implementation, a hydrocarbon pumping system includes a post assembly configured to sit on a well pad; a walking beam pivotally coupled to the post assembly; a first horsehead assembly coupled to a first end of the walking beam; and a second horsehead assembly coupled to a second end of the walking beam opposite the first end. The first horsehead assembly includes a first horsehead coupled to the first end of the walking beam, and a first sucker rod assembly coupled to the first horsehead, at least a portion of the first sucker rod assembly configured to oscillate within a first wellbore. The second horsehead assembly includes second horsehead coupled to the second end of the walking beam, and a second sucker rod assembly coupled to the second horsehead, at least a portion of the second sucker rod assembly configured to oscillate within a second wellbore different than the first wellbore. The system further includes a prime mover coupled to the walking beam and configured to driveably pivot the walking beam about the post assembly to simultaneously oscillate the first and second sucker rod assemblies within the respective first and second wellbores.
In an aspect combinable with the example implementation, the first horsehead includes a counterbalance weight to the second horsehead, and the second horsehead includes a counterbalance weight to the first horsehead.
In another aspect combinable with any of the previous aspects, the first horsehead is the only counterbalance weight to the second horsehead, and the second horsehead is the only counterbalance weight to the first horsehead.
Another aspect combinable with any of the previous aspects further includes a gear assembly coupled to the prime mover; a first pitman assembly coupled to the gear assembly and the walking beam at a first location; and a second pitman assembly coupled to the gear assembly and the walking beam at a second location different than the first location.
In another aspect combinable with any of the previous aspects, the first location is between the first end of the walking beam and a pivot point of the walking beam, and the second location is between the second end of the walking beam and the pivot point of the walking beam.
In another aspect combinable with any of the previous aspects, the prime move is a single prime mover.
In another aspect combinable with any of the previous aspects, the single prime mover includes an electric motor or a natural gas engine.
In another aspect combinable with any of the previous aspects, the single prime mover is coupled to the gear assembly though a belt or chain.
In another example implementation, a method for operating a hydrocarbon pumping system includes operating a prime mover that is coupled to a walking beam of the hydrocarbon pumping system; based on operating the prime mover, pivoting the walking beam about a pivot where the walking beam is coupled to a post assembly of the hydrocarbon pumping system; and oscillating a first horsehead assembly coupled to a first end of the walking beam by pivoting the walking beam about the pivot. The first horsehead assembly includes a first horsehead coupled to the first end of the walking beam, and a first sucker rod assembly coupled to the first horsehead. The method further includes oscillating at least a portion of the first sucker rod assembly within a first wellbore by oscillating the first horsehead assembly; and oscillating, simultaneous with oscillating the first horsehead assembly, a second horsehead assembly coupled to a second end of the walking beam opposite the first end by pivoting the walking beam about the pivot. The second horsehead assembly includes a second horsehead coupled to the second end of the walking beam, and a second sucker rod assembly coupled to the second horsehead. The method further includes oscillating at least a portion of the second sucker rod assembly within a second wellbore different than the first wellbore by oscillating the second horsehead assembly.
An aspect combinable with the example implementation further includes counterbalancing a weight of the second horsehead during oscillation of the second horsehead assembly with the first horsehead; and counterbalancing a weight of the first horsehead during oscillation of the first horsehead assembly with the second horsehead.
Another aspect combinable with any of the previous aspects further includes producing a first hydrocarbon fluid from the first wellbore by oscillating the portion of the first sucker rod assembly in the first wellbore; and producing a second hydrocarbon fluid from the second wellbore by oscillating the portion of the second sucker rod assembly in the second wellbore.
In another aspect combinable with any of the previous aspects, producing the first hydrocarbon fluid and producing the second hydrocarbon fluid occurs simultaneously or substantially simultaneously.
Another aspect combinable with any of the previous aspects further includes transferring rotary motion from the prime mover to a gear assembly coupled to the prime mover; translating rotary motion from the gear assembly to the oscillatory motion of the first horsehead assembly through a first pitman coupled between the gear assembly and the walking beam at a first location; and translating rotary motion from the gear assembly to the oscillatory motion of the second horsehead assembly through a second pitman coupled between the gear assembly and the walking beam at a second location.
In another aspect combinable with any of the previous aspects, the first location is between the first end of the walking beam and a pivot point of the walking beam, and the second location is between the second end of the walking beam and the pivot point of the walking beam.
In another aspect combinable with any of the previous aspects, the prime mover is a single prime mover.
In another aspect combinable with any of the previous aspects, the single prime mover includes an electric motor or an internal combustion engine.
In another aspect combinable with any of the previous aspects, transferring rotary motion from the prime mover to the gear assembly coupled to the prime mover includes transferring rotary motion from the single prime mover to the gear assembly coupled to the single prime mover though a belt or chain.
In another aspect combinable with any of the previous aspects, oscillating the portions of the first and second sucker rod assemblies includes: moving the portion of the first sucker rod assembly within the first wellbore in a downhole direction while moving the portion of the second sucker rod assembly within the second wellbore in an uphole direction; and moving the portion of the first sucker rod assembly within the first wellbore in an uphole direction while moving the portion of the second sucker rod assembly within the second wellbore in a downhole direction.
In another example implementation, a sucker rod pumping unit includes a surface beam pivotally coupled to a post assembly mountable on a multi-well pad; two horseheads, each of the two horseheads connected to a particular end of the surface beam, each of the two horseheads including a counterweight to the other of the two horseheads; two sucker rod assemblies, each of the two sucker rod assemblies attached to one of the two horseheads; and one rotary machine driveably coupled to the two sucker rod assemblies through the surface beam.
In an aspect combinable with the example implementation, the one rotary machine is coupled to the surface beam through a gear reducer.
In another aspect combinable with any of the previous aspects, the gear reducer is coupled to the surface beam through two link members.
In another aspect combinable with any of the previous aspects, the two link members are attached to the surface beam at opposed halves of the surface beam.
Implementations of a hydrocarbon pumping system according to the present disclosure may include one or more of the following features. For example, the hydrocarbon pumping system may provide for a multi-well pad set up for unconventional resource developments, which may benefit from drilling sets of identical adjacent wells from the same pad. As another example, the hydrocarbon pumping system may provide for a single pumping unit with a single prime mover to produce two wells simultaneously. As yet another example, the hydrocarbon pumping system may reduce or help reduce capital cost of surface pumping units, as well as reduce or help reduce a power consumption needed to operate such surface pumping units. Such capital and operating expenses may represent a significant percentage of a hydrocarbon production operating cost over a well life cycle. As another example, the hydrocarbon pumping system may eliminate a need for external balance weights to provide counter balance effects, thus further reducing a power consumption of a surface pumping system. As yet another example, the hydrocarbon pumping system may provide for a commercial benefit by reducing an amount of consumed power to produce two wells using a single prime mover, which may reduce an operational expenditure over the wells' life cycles and may make some uneconomical fields be more economical to produce.
The details of one or more implementations of the subject matter described in this disclosure are set forth in the accompanying drawings and the description below. Other features, aspects, and advantages of the subject matter will become apparent from the description, the drawings, and the claims.
The illustrated implementation of the sucker rod pump unit 105 includes a surface beam 102 (also called a walking beam 102) that is pivotally mounted to a post assembly 106 that is mounted on the well pad 104. As shown, the beam 102 is pivotally attached to the post assembly 106 at a pivot 108 (or pivot point 108). In some aspects, the pivot 108 may be near or at a lengthwise center of the surface beam 102.
Also coupled (e.g., attached) to the surface beam 102 are lever assemblies 116a and 116b, each of which is pivotally coupled to a gear assembly 112. As shown in this example, each lever assembly 116a and 116b (also called pitman 116a and pitman 116b) is attached or coupled to the surface beam 102 at an independent location on the beam 102. For example, lever assembly 116a is coupled to the surface beam 102 at location 122a, which is between the pivot 108 and a first end 120a of the surface beam 102. Lever assembly 116b is coupled to the surface beam 102 at location 122b, which is between the pivot 108 and a second end 120b of the surface beam 102. As further shown in this example, each lever assembly 116a and 116b may be comprised of multiple links, which are pivotally coupled together. In this example, for instance, each lever assembly 116a and 116b include two links that are pivotally coupled together, with one link coupled to the surface beam 102 and another link coupled to the gear assembly 112.
In the illustrated example, the gear assembly 112 may include one or multiple gears that act as gear reducer. Although the term “gear” is used, other rotary devices that link together (e.g., wheels and belts or chains, or other spoked components) and function to change and/or transfer rotational speed and movement from one component (e.g., the prime mover 110) to another component (e.g., the lever assemblies 116a and 116b) are also contemplated by the present disclosure. In some aspects, as shown in
In this example, the prime mover 110 may be, for instance, an electric motor, a natural gas or diesel engine, or other rotary machine that uses a fuel to generate rotational power and torque. In the illustrated implementation of the hydrocarbon pumping system 100, the prime mover 110 is a single prime mover 110, e.g., a single electric motor, or a single engine, etc. Coupled to the gear assembly 112 and therefore to the surface beam 102, the single prime mover 110 may operate to provide rotational power to the sucker rod pump unit 105 to produce hydrocarbon fluids from two wells at the same time or substantially simultaneously. In this example, the prime mover 110 and gear assembly 112 are mounted close to or at a point directly below the pivot 108.
Turning specifically to
At the surface 101, a pumping tee 132a is positioned at a top of a surface casing 136a. A fluid discharge 134a extends from the pumping tee 132a and is fluidly coupled to the wellbore 146a to receive hydrocarbon fluids 150a from one or more subterranean zones under the terranean surface 101, through perforations 148a (e.g., through a production casing or string) and into the wellbore 146a. The fluid discharge 134a may include or connect to a hydrocarbon fluid pipeline. Also installed in the wellbore 146a, in this example, is a tubing string 138a (e.g., a production tubing string).
Attached to the sucker rod 140a is a plunger 142a that, during operation of the sucker rod pump unit 105, oscillates into and out of a barrel 144a within the wellbore 146a to lift the hydrocarbon fluids 148a within the wellbore 146a toward the surface 101 and into the fluid discharge 134a.
A second horsehead assembly includes a horsehead 118b that is coupled or attached to the surface beam 102 at the second end 120b and a sucker rod assembly 124b coupled to the horsehead 118b. The sucker rod assembly 124b includes, in this example implementation, a bridle 126b that is attached to the horsehead 118b and is also coupled to a clamp 128b. The clamp 128b is, in turn, coupled to a rod (polished rod) 130b that is coupled to or part of a sucker rod 140b. The polished rod 130b and/or sucker rod 140b extends into a wellbore 146b at the terranean surface 101.
At the surface 101, a pumping tee 132b is positioned at a top of a surface casing 136b. A fluid discharge 134b extends from the pumping tee 132b and is fluidly coupled to the wellbore 146b to receive hydrocarbon fluids 150b from one or more subterranean zones under the terranean surface 101, through perforations 148b (e.g., through a production casing or string) and into the wellbore 146b. The fluid discharge 134b may include or connect to a hydrocarbon fluid pipeline. Also installed in the wellbore 146b, in this example, is a tubing string 138b (e.g., a production tubing string).
Attached to the sucker rod 140b is a plunger 142b that, during operation of the sucker rod pump unit 105, oscillates into and out of a barrel 144b within the wellbore 146b to lift the hydrocarbon fluids 148b within the wellbore 146b toward the surface 101 and into the fluid discharge 134b.
In this example implementation of the sucker rod pump unit 105 and unlike conventional sucker rod pumping systems, there is no independent counterweight (i.e., a weighted component that serves only as a counterweight to the horsehead), which is typically coupled or attached to an end of a surface beam opposite a horsehead. An independent counterweight, conventionally, acts to reduce an amount of work required by the sucker rod pumping system (e.g., a prime mover of the system) during operation. In this example implementation of the sucker rod pump unit 105, the horsehead 118a acts as a counterbalance weight to the horsehead 118b during operation of the sucker rod pump unit 105, while the horsehead 118b acts as a counterbalance weight to the horsehead 118a during operation of the sucker rod pump unit 105; thus, the sucker rod pump unit 105 is self-balanced. Thus, in this example implementation of the sucker rod pump unit 105, no additional counterbalance weight components (besides the horseheads 118a and 118b) are required or necessary.
Turning specifically to
Method 300 may continue at step 304, which includes based on operating the prime mover, pivoting the walking beam about a pivot where the walking beam is coupled to a post assembly of the hydrocarbon pumping system. For example, the prime mover 110 operates to drive the gear assembly 112, which is coupled to both of the lever assemblies 116a and 116b. As the lever assemblies 116a and 116b are coupled to the walking beam 102, the rotational power of the prime mover 110 is translated to pivotal movement of the walking beam 102 about the pivot 108.
Method 300 may continue at step 306, which includes oscillating a first horsehead assembly coupled to a first end of the walking beam by pivoting the walking beam about the pivot. For example, as the walking beam 102 pivots about the pivot 108, the horsehead 118a moves up and down in a linear or slightly curved path.
Method 300 may continue at step 308, which includes oscillating at least a portion of the first sucker rod assembly within a first wellbore by oscillating the first horsehead assembly. For example, when the horsehead 118a is moving up and down in the linear or slightly curved, the sucker rod assembly 124a oscillates in an upward and downward motion, following the motion of the horsehead 118a. Thus, as the sucker rod assembly 124a oscillates, at least the sucker rod 140a (and plunger 142a) oscillate in the wellbore 146a.
Method 300 may continue at step 310, which includes oscillating, simultaneous with oscillating the first horsehead assembly, a second horsehead assembly coupled to a second end of the walking beam opposite the first end by pivoting the walking beam about the pivot. For example, as the walking beam 102 pivots about the pivot 108, the horsehead 118b moves up and down in a linear or slightly curved path. As the horsehead 118b is connected to an opposite end of the walking beam 102 from the horsehead 118a, the horsehead 118b moves substantially in an opposite direction (with respect to gravity) as the horsehead 118a. Thus, as the horsehead 118b moves up (with respect to gravity), the horsehead 118a moves down (with respect to gravity). As the horsehead 118a moves up (with respect to gravity), the horsehead 118b moves down (with respect to gravity).
Method 300 may continue at step 312, which includes oscillating at least a portion of the second sucker rod assembly within a second wellbore different than the first wellbore by oscillating the second horsehead assembly. For example, when the horsehead 118b is moving up and down in the linear or slightly curved, the sucker rod assembly 124b oscillates in an upward and downward motion, following the motion of the horsehead 118b. Thus, as the sucker rod assembly 124b oscillates, at least the sucker rod 140b (and plunger 142b) oscillate in the wellbore 146b.
By oscillating both portions of the sucker rod assemblies 124a and 124b, the hydrocarbon pumping system 100 may produce (and method 300 may include a step of producing) hydrocarbon fluids 150a and 150b from both of wellbores 146a and 146b using prime mover 110 (e.g., a single prime mover 110). In some aspects, hydrocarbon fluids 150a and 150b may be produced (e.g., circulated to and through the fluid discharges 134a and 134b, respectively) at the same time, i.e., simultaneously. In some aspects, such as due to the opposed oscillation of the respective sucker rod assemblies 124a and 124b in which one of the sucker rod assemblies is moving uphole while the other of the sucker rod assemblies is moving downhole, hydrocarbon fluids 150a and 150b may be produced (e.g., circulated to and through the fluid discharges 134a and 134b, respectively) sequentially, i.e., substantially simultaneously.
A number of implementations have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the disclosure. For example, example operations, methods, or processes described herein may include more steps or fewer steps than those described. Further, the steps in such example operations, methods, or processes may be performed in different successions than that described or illustrated in the figures. Accordingly, other implementations are within the scope of the following claims.
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