• 专利附录
  • 专利说明
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    • 专利摘要:
    PUMPING UNIT, DEVICE AND METHOD OF PUMPING A FLUID. These are systems adaptable to a surface pump unit that include a low inertia pump unit mechanism that has a pneumatic counterbalance assembly, as well as methods for using such systems for underground fluid recovery. The system has the ability to be integrated with well management automation systems thus allowing a response to active control commands, and automatically changing and/or maintaining a counterbalance force in the pump unit by adding or removing it. if the air mass of a containment vessel associated with the pumping unit.
    公开号:BR112014010986B1
    申请号:R112014010986-9
    申请日:2012-11-08
    公开日:2021-05-25
    发明作者:David Doyle
    申请人:Lufkin Industries, Inc;
    IPC主号:
    专利说明:

    CROSS REFERENCE WITH RELATED ORDERS
    [0001] This application claims priority to Provisional Patent Application Serial Number US 61/557,269, filed November 8, 2011, the contents of which are incorporated herein by reference in their entirety. STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT
    [0002] Not applicable. REFERENCE TO THE APPENDIX
    [0003] Not applicable. BACKGROUND OF THE INVENTION FIELD OF THE INVENTION
    [0004] The inventions disclosed and taught in this document generally relate to mechanical counterbalances and more specifically refer to pneumatic counterbalances suitable for use in machinery such as linear rod pumping units. DESCRIPTION OF RELATED TECHNIQUE
    [0005] Rocker pump units and their upstream drive components are exposed to a wide range of loading conditions. These vary by well application, the type and proportions of the pump unit linkage mechanism and offset compatibility. The primary function of the pumping unit is to convert the rotary motion of the primary mover (electric motor or motor mechanism) into reciprocal motion above the wellhead. This movement is, in turn, used to drive a reciprocating well-bottom pump through a connection through a pump rod column. An example of a conventional pumping unit arrangement is illustrated generally in Figure 1 and will be discussed in more detail in this document.
    [0006] The "4-bar linkage" comprising the linkage rocker arm, Pitman, cranks and connecting bearings processes the polished shaft load of the well into a component of the gearbox torque (well torque). The other component, counterbalance torque, is adjusted in the pump unit to yield the lowest final torque in the gearbox. Offset torque can be adjusted in magnitude, but typically not in phase (timing) in relation to the well load torque. In crank balanced machines, the counterbalance torque will appear sinusoidal since it is effectively a mass that receives the actuation of gravity as it rotates around a fixed horizontal axis. The basic computation for the pump unit crankshaft torque is: Tfinal = Twell - Tebal
    [0007] Counterbalance can be supplied in numerous forms in the range of rocker mounted counterweights, to crank mounted counterweights, to compressed gas springs mounted between the rocker arm and base frame, to name but a few. The primary objective in offset incorporation is to deflect a portion of the well load approximately equal to the average of the peak and minimum polished rod loads found in the pumping cycle. This technique typically minimizes torque and working forces on upstream driveline components reducing their load capacity requirements and maximizing energy efficiency.
    [0008] Well loads on the polished rod are processed by connecting 4 rods in the crankshaft torque at varying ratios depending on the relative angles of the 4 rod connecting members (ie stroke position). Simultaneously, the counterbalance torque produced by one of the several methods above interacts with the well load torque, negating a large percentage of it. The resulting final torque exposed to the crankshaft is generally only a small fraction of the original well load torque. Note in the diagram to the right that the well torque (the final torque component results from the polished rod load) is highly variable, both in magnitude and in phase angle (timing). In contrast, the counterbalance torque is smooth and sinusoidal. Its phase angle is established as an attribute of the pump unit design selected for the broadest applicability - and is generally not adjustable. Phase angle and magnitude mismatches between well and counterbalance torque curves are the source of "softness" in the final torque transmitted through the gear reducer and upstream drive line elements. These elements must be selected with sufficient capacity to survive the peak load conditions encountered during the pumping cycle. Since the actual pumping work performed during the cycle is equivalent to:
    It is evident that the “softness” in the final torque curve results in inefficient use of these drive line elements. In fact, the final torque curve in the example above immerses in negative (regenerative) values at multiple locations during the cycle, further reducing the final work done.
    [0009] The main source of variability in the well torque curve is the elastic response of the pump rod string to dynamic loads transmitted through it from the downhole pump and the surface pump unit. The rod column, sometimes kilometers long, behaves over long distances much like a spring. It elongates when exposed to internal tensile stress and when the stress is variable, the response is often oscillatory in nature. The system is somewhat dampened due to its submersion in a viscous fluid (water and oil), but the movement profile of the drive pumping unit combined with the pump step function loading generally leaves little time for the oscillations to deteriorate before the next disturbance is encountered.
    [0010] The diagram shown in Figure 3 illustrates in general some of the interactions at work in a typical rod pumping chain. The surface pump unit gives continuously varying movement to the polished rod. The connecting pump rod column, modeled as a series of springs, masses, and dampers, responds to accelerations in the speed of sound, sending variable voltage waves downward along its length to alter its own motion. It also stretches as it builds up the force necessary to move the downhole pump and fluid. The pump, freeing itself from the effects of friction and fluid inertia, tends to recover under the elastic force of the pump rods, initiating an additional oscillatory response within the column. Travel voltage waves from multiple sources interfere with each other along the stem column (some constructively, some deconstructively) as they traverse its length and reflect load variations back to the pumping unit. surface where they can be measured and graphed as part of the surface dynamometer card. The resulting surface dynamometer card, like the general example in Figure 4, shows superimposed indicators of large-scale rod stretch, damped oscillations, friction, as well as inertia effects, all in varying amounts depending on well and bore application. geometry of the pumping unit.
    [0011] Problem addressed: Fixed proportion 4-bar linkage geometries observed in typical rocker arm pump units exhibit application preferences for a relatively narrow band of operating conditions (ie, conventional units for upslope dynamometer cards , Mark II for descending slope cards, Reverse Mark for level cards, etc.). These preferences are critical for a particular bonding geometry and are very difficult to change. This is not to say that a Mark II (Lufkin Industries, Inc.) pump unit cannot operate with an up-tilt board, merely that an ideal efficiency preference exists and that performance consequences are created when they are not. obeyed. The diagrams in Figures 5 and 6 provide some illustration of this point. Permissible load diagrams (PLD) for counterbalanced and similarly sized Conventional and Mark II balancing units (Lufkin, Lufkin, TX industries) are shown along with a surface dynamometer card for comparison in Figure 5. The load diagrams Allowables display the polished rod load that would be required to create crankshaft torque equivalent to the gear reducer torque ratio for a given pump unit design and counterbalance adjustments. It can be seen from the format of the allowable load diagrams in Figure 5 that the conventional pump unit exhibits a preference for dynamometer cards with an upward slope trend (moving from left to right). In contrast, as shown in both Figure 5 and Figure 6, the Mark II unit shows a preference for tilt-down cards. The dynamometer card, in this instance, also shows a slight upward trend, which makes it conform a little better to the PLD of the conventional unit. Note that both pump units would operate close to their upstream drive line capacities, given the relative proximity of the peak and minimum polished rod load to their respective PLDs. However, the area of the Mark II unit's PLD is substantially larger than that of the Conventional unit, indicating that it has the capacity to do more work during its pumping cycle. The extra available working capacity of the Mark II pump unit would be underutilized in this particular application.
    [0012] An unfortunate reality is that rod pumping dynamometer cards almost never have the vaguely hourglass shape which would maximize the working potential of most rocker arm pumping units, at least not under near constant rotational speed conditions under which they were designed to operate.
    [0013] Automation technology packages for rod pumping applications have been around for several years. Operating wells can be monitored by a variety of methods to collect surface movement and load information, then, by computer simulation, diagnose such things as overload conditions or the appearance of downhole issues in the range. from pump-off (incomplete pump filling) to rod buckling to worn or damaged equipment. The predictive simulations performed by many of these rod pump control (RPC) systems are suitable for accurately modeling the elastic-dynamic behavior of the rod pumping chain (pump, rods and pump unit) with program data input relatively minimal.
    [0014] More recently, variable speed drives (VSD) have been integrated into rod pumping unit applications and, in conjunction with RPC technology, have markedly improved the longevity and efficiency of many rod pumping systems. Today, it is relatively common to see operating pump units being monitored by RPCs who can detect system anomalies and detect corrective action commands to a VSD to, for example, adjust the pump speed to decrease in response to pump-off conditions detected or possibly to shut down in response to excessive loading. If used in conjunction with supervisory control and data acquisition (SCADA) technology, a stem and well pumping system can be remotely monitored and controlled, making it possible to identify and respond to potential equipment or maintenance issues. change production goals from a control center miles away or perhaps continents of distance.
    [0015] The relatively poor pumping unit capacity pictured in the above case can be at least partially remedied through active speed control. Pumping unit dynamometer cards tend to be quite repetitive from cycle to cycle and speeding up and slowing down at strategic points in the cycle could dynamometer card shape to or truncate load additions, improve drive line capacity utilization, increase production or improve system efficiency. Active control of the pumping unit's force/motion profile could also yield significant benefit in terms of rod, piping and downhole pump life. In certain instances, such as using video fiber pump rods, RPC and VSD technologies can be used in conjunction with search algorithms, actively controlling the motion profile to produce large downhole pump displacements while protecting simultaneously the stem column of the emergence of buckling, as an example.
    [0016] Unfortunately, the flywheel effect produced by massive rotating components in the pumping unit resists rapid speed changes. Cranks, counterweights, gears, pulleys, brake drums and other rotating components in the system contribute to the overall flywheel effect and require significant torque effort to change its rotational speed. This presents a substantial impediment to active control scenarios such as those mentioned above. Attempts to substantially change the speed in the pumping cycle with a VSD to date have generally consumed disproportionately more power, which negatively affects the cost of operation. Pumping unit designs with substantially reduced mass moments of inertia appear to be a prerequisite for fully implementing active speed control in rod pumping.
    [0017] Mass-based offset systems have problems in continually maintaining optimal offset as well conditions change. The fluid level in the well casing ring tends to decline with production over time. As the fluid level drops, the rod pump system needs to lift the fluid to a great depth, increasing the amount of counterbalance needed. In contrast, if the well is closed for an extended period of time, the fluid level will typically rise, reducing the necessary offset proportionately. Failure to maintain proper balance can lead, at best, to inefficient use of power and, at worst, to upstream equipment failures due to overload. Generally, counterbalance adjustments in existing rocker unit designs are performed manually by repositioning, adding or removing counterweights in a labor-intensive equipment and process that requires shutting down and restricting the unit, entry into a hazardous area, use of equipment, and expensive cranes and temporary loss of production for the operator.
    [0018] Changing stroke length is also a manual process involving the same steps as those above (the unit needs to be rebalanced following a course change) with the notable additions that the pump unit needs to be decoupled from the load of shaft, crank pins need to be removed and moved to another hole in the crank arm, the crank arms need to be repositioned by crane during stroke repetition and the downhole pump needs to be spaced again, also by crane, before to re-establish the service.
    [0019] Downhole pump valve testing (valve check) is generally performed by stopping the movement of the pumping unit in the upstroke or in the downstroke and measuring the rate at which the polished rod load declines or rises as a means of assessing leakage rates at pump valves. The testing method typically requires the use of a portable dynamometer and insertion of a calibrated load cell between the carrier bar and rod clamp.
    [0020] Large, heavy moving parts close to ground level require relatively extensive safety surveillance to prevent inadvertent contact with personnel while the pump unit is in motion.
    [0021] The inventions disclosed and taught in this document are directed to adaptable surface pump units that include and combine automation technology with a low inertia pump unit mechanism with the ability to respond to active control commands from a system of well management automation, thereby enabling the surface pump unit to change in response to changing well conditions, where the pump unit has the ability to self-optimise, self-protect and safeguard equipment from within. of the well, while at the same time presenting a small environmental footprint designed so that typical safety hazards are eliminated or reduced, minimizing the need for warning signage. Such pump unit systems can automatically add and change and maintain the counterbalance force by controlling the addition or elimination of fluid mass (eg, air) from a containment vessel associated with the pump unit. DESCRIPTION OF THE INVENTION
    [0022] The objectives described above and other advantages and features of the invention are incorporated in the application as presented in this document and in the appendices and associated drawings relating to systems and methods for improved pumping units for use with a hydrocarbon production well, wherein the pumping unit includes an assembly to automatically change and maintain the counterbalance force in unit operation during so as to actively control the movement and/or force of the rod column, wherein the system exhibits low inertia.
    [0023] According to selected aspects of the disclosure, an adaptive surface pumping unit that combines automation technology with a low inertia pumping unit mechanism with the ability to respond to active control commands from the management automation system. well, thereby adapting to changing well conditions. Such a pumping unit has the ability to self-optimise, self-produce and safeguard expensive downhole equipment. Additionally, such a pumping unit has a small environmental footprint where it is designed in such a way that safety hazards are eliminated or reduced to the bridge where warning and surveillance signaling requirements are minimal
    [0024] Also described is a device and associated method of operation for automatically changing and maintaining the counterbalance force by adding or removing air mass from the pumping unit containment vessel. The method for developing target offset air pressure is based on linear regression analysis of position data and measured well load along with peak and minimum well loads. Such a method may also include a system and method for correcting the counterbalance air pressure by recursive error reduction methods comparing measured and target air pressure values. An alternative yet equally viable variant of the method for air counterbalance pressure correction by recursive error correction may include comparing peak magnitude upstroke and downstroke motor torque and actual values and balancing these.
    [0025] According to further aspects of the present disclosure, a device and method for automatically changing the compressible volume within a pneumatic pressure vessel to counterbalance a pumping unit is described, the method including displacing a portion of the compressible volume with an incompressible substance (or mixture of incompressible substances), thus changing the envelope of the allowable charge shape for the pumping unit. Such incompressible substances suitable for use include non-corrosive fluids and liquids, such incompressible substance being contained in an inflatable bag, diaphragm or independent collector assembly. In addition to this aspect, methods of transferring incompressible liquid between the reservoir and the pressure vessel are described, the methods including the use of an electrically and automatically actuated pump and/or valve in response to commands issued by a controller pump with rod (RPC).
    [0026] In further aspects of the present disclosure, a device and method for automatically changing the compressible volume within a pneumatic pressure vessel to counterbalance a pumping unit are described, the methods including displacing a portion of the compressible volume with a piston mobile, thus changing the format of the permissible load envelope for the pumping unit.
    [0027] In yet another of the present disclosure, a system and method to actively control the movement of a pumping unit with a rod to improve the volume of fluid production by increasing the work performed in the pumping cycle, with increments. The method includes analyzing well dynamometer data, comparing the dynamometer data to one or more pump unit allowable load envelopes, and varying the rod pump unit pumping speed across the dynamometer regions to reduce load and torque where necessary, and/or expand the vertical load range on the dynamometer card through underutilized sections of the allowable loading envelope to maximize cycle work (production) thereby protecting the stem column from conditions arising. such as buckling or excessive tension levels.
    [0028] According to a first disclosure of the present disclosure, surface pumping units for obtaining fluids from an underground formation are described, as well as methods for their use, the units including a pneumatic pressure vessel in operative communication with the pumping unit, wherein the pressure vessel is capable of automatically changing the compressible volume within the pressure vessel to counterbalance the pumping unit by displacing a portion of the compressible volume with an incompressible substance. BRIEF DESCRIPTION OF THE DRAWINGS
    [0029] The following figures form part of this specification and are included to further demonstrate certain aspects of the present invention. The invention may be better understood by reference to one or more of these figures in combination with the detailed description of the specific disclosures presented herein.
    [0030] Figure 1 illustrates a diagrammatic side elevation view of an exemplary rocker pump unit.
    [0031] Figure 2A illustrates general schematic pump cards in the bore or surface.
    [0032] Figure 2B illustrates a schematic illustration of well load torque versus crank angle.
    [0033] Figure 3 illustrates a general scheme of the rod pumping predictive analysis process.
    [0034] Figure 4 illustrates schematic pump cards for different positions in the pumping cycle and shows the operation of valves in a typical pumping system.
    [0035] Figure 5 illustrates a general scheme of allowable loads and an associated dynamometer card for a conventional and Mark II pumping unit.
    [0036] Figure 6 illustrates an alternative presentation of the data in Figure 5, highlighting the unused work areas for the two pumping units.
    [0037] Figure 7 illustrates a partial cutaway view in perspective of an exemplary system in accordance with aspects of the present disclosure.
    [0038] Figure 8 illustrates a front cross-sectional view of the assembly of Figure 7.
    [0039] Figure 9 illustrates a cross-sectional view from top to bottom of the assembly of Figure 7.
    [0040] Figures 10A and 10B illustrate the exemplary system of Figure 7 in the fully retracted (10A) and fully extended (10B) positions.
    [0041] Figure 11 illustrates an exemplary permissible load diagram and dynamometer data graph of a system in accordance with the present disclosure.
    [0042] Figure 12 illustrates a schematic view of a pressure actuation assembly according to the present disclosure.
    [0043] Figure 13 illustrates a graph showing exemplary allowable loading and counterbalance making tilt changes that result from an auxiliary pressure vessel partially filled with an incompressible fluid.
    [0044] Figure 14 illustrates an initial dynamometer data plot derived from a rod pump controller in association with a system of the present disclosure.
    [0045] Figure 15 illustrates an exemplary linear regression model of dynamometer data plot data in accordance with aspects of the present disclosure.
    [0046] Figure 16 illustrates an exemplary dynamometer data plot following an exemplary system balance sequence in accordance with the present disclosure.
    [0047] Figure 17 illustrates a general graph that corresponds PLD slope (permissible slope diagram) to a target value, in accordance with aspects of the present disclosure.
    [0048] Figure 18 illustrates an exemplary cycle time interval in accordance with the present disclosure.
    [0049] Figure 19 illustrates a general flowchart of steps for rod column motion and/or force control methods using the systems of the present disclosure.
    [0050] Although the inventions disclosed herein are susceptible to various modifications and alternative forms, only a few specific disclosures have been shown by way of example in the drawings and are described in detail below. The figures and detailed descriptions of the specific disclosures are not intended to limit the breadth or scope of the concepts of the invention or the appended claims in any way. Rather, figures and detailed written descriptions are provided to illustrate the concepts of the invention to an individual of ordinary skill in the art and to enable such an individual to produce and use the concepts of the invention. DESCRIPTION OF ACHIEVEMENTS OF THE INVENTION
    [0051] The figures described above and the written description of specific structures and functions below are not presented to limit the scope of what the Claimants have devised or the scope of the appended claims. Rather, the Figures and written description are provided to teach an individual skilled in the art how to produce and use the inventions for which patent protection is sought. Those skilled in the art may note that not all features of a commercial disclosure of the inventions are described or shown for the sake of clarity and understanding. Those of skill in the art may also note that the development of an actual commercial disclosure that incorporates aspects of the present inventions will require numerous implementation-specific decisions to achieve the developer's ultimate goal for commercial disclosure. Such deployment-specific decisions may include, and are likely without limitation, compliance with system-related, business-related, government-related, and other restrictions, which may vary by specific deployment, location, and from time to time. While a developer's efforts can be complex and time-consuming in an absolute sense, such efforts would nevertheless be a routine task for those skilled in the art who have the benefit of this disclosure. It is to be understood that the inventions disclosed and taught herein are susceptible to numerous and various modifications and alternative forms. Lastly, the use of a singular term, such as but not limited to “one”, is not intended to limit the number of items. In addition, the use of relational terms, such as, but not limited to, "top", "bottom", "left", "right", "top", "bottom", "bottom", "top", " side” and the like are used in the written description for clarity in specific reference to the Figures and are not intended to limit the scope of the invention or the appended claims.
    [0052] Particular disclosures of the invention may be described below with references to block diagrams and/or operational illustrations of methods. It should be understood that each block of block diagrams and/or operational illustrations and combinations of blocks in block diagrams and/or operational illustrations can be implemented by analog and/or digital hardware, and/or computer program instructions . Such computer program instructions may be provided to a general purpose computer processor, special purpose computer, ASIC and/or other programmable data system. The executed instructions can create structures and functions for implementing actions specified in block diagrams and/or operational illustrations. In some alternative implementations, the functions/actions/structures cited in the figures may occur out of the order cited in the block diagrams and/or operational illustrations. For example, two operations shown to occur in succession may actually be performed substantially simultaneously or the operations may be performed in reverse order, depending on the functionality/actions/structures involved.
    [0053] Applicants have created pumping unit systems and methods of use thereof that exhibit low inertia during use and have the ability to interface with and respond to active controls and commands from a well management automation system. to adapt to changing well conditions during unit operation. Such pump unit systems include one or more fluid pressure vessels in fluid pressure communication between themselves and the pump unit, to allow for the automatic change and maintenance of counterbalance forces of the pump unit, such as by adding or removing fluid mass from one or more pressure vessels.
    [0054] In order that the structure, operation and advantages of the pump unit systems of the present invention may be better understood, a typical pump unit system 10 is shown in Figure 1. According to the disclosure pictured, the system 10 is an oil well recovery pump for recovering fluid from beneath the surface of the earth 9. The pumping unit is generally indicated at 10 and includes a base 11 which is placed on a foundation adjacent to a wellbore. A plurality of integral support posts 14, each of which is known in the art as a Samson post, are mounted to the base 11 and extend upward to a center bearing or pivot connection 20. A rocker arm 18 is mounted on center bearing 20 so that the center bearing is the pivot point for rocker arm oscillation. A rocker arm 16 is fastened to a rocker arm front end 18, and a steel cable 22 is fastened to and extends between the rocker arm and a carrier bar 15. The carrier bar 15, in turn, is fastened to a stem column 26, which extends into the well through the wellhead 12 (alternatively referred to as a stuffing box, tee, etc.). As described above, wire rope 22 follows the curve of rocker head 20 as the front end of rocker arm 18 raises and lowers, which enables pump unit 10 to provide a vertical stroke of rod column 26. The system 10 comprises rocker head 16 positioned at one end of rocker arm 18, which is actuated between a first position, eg top dead center (TDC), and a second position, eg bottom dead center (BDC) as part of the operation of system 10 to recover fluid from an underground formation. To this end, as the rocker arm 18 is actuated between its top and bottom position, the rocker head 16 undergoes an up and down movement. Consequently, brake line cable 19, which extends between rocker head 16 and polished rod 24, causes polished rod 24 to reciprocate in wellhead 12. This action finally causes fluid to be pumped into the surface.
    [0055] As described above, a primary mover or a drive unit 22 drives the oscillation of the rocker arm 18 around the center bearing or pivot connection 20. The drive unit 30 is typically an electric motor or a motor mechanism. combustion and is shown herein as an electric motor for the purpose of convenience. Motor 30 is connected by drive belts (such as V-belt 32) and pulleys (not shown) to a gear reducer 34. The gear reducer 34 is located between and is pivotally connected to one or more crank arms 36 , and each of the crank arms is, in turn, pivotally connected to a respective arm of a pair of Pitman 38 arms. Each Pitman 38 arm, in turn, is connected to an equalizer bar (not shown) that stretches between Pitman's arms.
    [0056] This connection of motor 30 to gear reducer 34, crank arms 36, Pitman arms 38 and rocker arm 18 enables the rocker arm to be driven in an oscillating manner around center bearing 20. The use of two crank arms 36 and two Pitman arms 38 is known as a four-bar lever system, which converts rotational movement of motor 30 into reciprocal motion in rocker head 16. When motor 30 is disabled and you want to stop the movement of the motor. rocker arm 18, a brake lever is actuated by an operator, as known in the art.
    [0057] The system 10 in Figure 1 is preferably equipped with a controller 40 coupled to a variable frequency drive (VFD) 42 via a communication path 44. The controller 40, sometimes equivalently referred to as a well manager in site, preferably includes a microprocessor and controller software. The VFD 42 also includes a microprocessor and has its own VFD software. The VFD 42 controls the speed of the primary mover 30 as a function of control signals from the controller 40. The rotational power output of the primary mover 30 is transmitted by a drive belt 32 to a gearbox unit. The gearbox unit 34 reduces the rotational speed generated by the primary mover 30 and imparts rotary motion to a crankshaft end, a crank arm 36 and a counterbalance pump unit weight 28. of crank 36 is converted to reciprocal movement by means of rocker arm 18.
    [0058] Figure 1 additionally shows a nominally vertical well having the normal well casing 50 extending from surface 9 to the bottom thereof. Positioned in the well casing 50 is a production line 51 which has a pump 52 located at the lower end. Pump keg 53 contains a foot valve 54 and a piston or piston 55 which in turn contains a rolling valve 56. The piston 55 is actuated by a pump rod with gasket 57 which extends from the piston 55 upwards through the surface production piping and is connected at its upper end by a coupling 58 to a polished rod 24 which extends through a packing joint 59 in the wellhead.
    [0059] The disclosure depicted in Figure 1 provides several advantages over other systems known in the art. These advantages are provided by numerous subsystems which, independently and working in combination with each other, allow the system 10 to provide, among other things, low operating torque, high operating efficiency, low inertia, movement and/or rod column force controlled and less work energy required. These subsystems, as will now be described in greater detail, will generally be referred to as an Offset Subsystem. COUNTERBALANCE SUBSYSTEM.
    [0060] In accordance with the preferred disclosure depicted in Figure 1, a combination of counterbalancing methods are used to provide what is sometimes referred to herein as a counterbalancing effect (CBE), which serves to reduce, or efficiently counterbalance, the well torque exerted on the system. As known to those of skill in the art, well torque generally refers to the torque placed on the system that results from the force of recovered fluid and work components lifted by the system during recovery. This counterbalancing effect maximizes energy efficiency. Referring again to Figure 1, counterbalance weights 28 are positioned at the end of the Pitman arm 38 on the opposite side of the center bearing/pivot connection 20 from the rocker head 16. During system 10 operation, torque exerted on the rocker arm 18 at the center of Sampson bearings 20 by the counterweight serves to counterbalance the torque exerted on the rocker arm 18 at the center of bearings 20 by the recovered fluid in combination with working components extending from the rocker head 16 (eg, polished rod 14 and cable of brake line 19). This torque can be considered “opposite torque”. In accordance with disclosures of the present disclosure, the torque exerted by the counterweight 28 is changed in response to the opposite torque exerted on the rocker arm 18. For example, it is typically desirable that the CBE be increased as the opposite torque increases, for example, during the upward stroke , and is decreased as the opposite torque decreases, for example, during the downstroke. CURRENT INVENTION
    [0061] In a disclosure of the present disclosure, the present invention comprises a pumping unit with a vertically oriented rod that has a linear motion vector 100 located adjacent to the wellhead for the purpose of reciprocating a downhole pump by means of connection via a pump rod column. One purpose of the invention is to facilitate the lifting of liquids from an underground well. In that disclosure, and with reference to Figures 7, 8 and 9, the present invention comprises a pressure vessel 101 statically connected to a mounting base frame 126. This base frame can be anchored to a stable foundation situated adjacent to the underground well. that produces fluid. Pressure vessel 101 may be comprised of a cylindrical or other suitable shaped casing body 148 constructed of cast or shaped plate or machined end flanges. Attached to the end flanges are the upper and lower pressure heads 150 and 130, respectively. Static seals 132 are incorporated into the flange/head joint to contain internal air pressure within vessel 101.
    [0062] Penetrating the upper and lower pressure vessel heads is a linear actuator assembly. This actuator assembly is comprised of a vertically oriented threaded screw 118, a planetary bearing nut 122, a striking plunger 108 in a pressing plunger tube 109, a thrust bearing assembly 141, a centering screw bearing 151, a guide tube 146, striker plunger guide bearings, an anti-rotation mechanism 160, a brake assembly, a motor 134, and seals 132 and O-rings (133, 143) for containing pressure fluid in the pressure vessel.
    [0063] Rolling bolt 118 is supported in a thrust bearing assembly mounted on the inner surface of the lower pressure vessel head 130. The lower portion of the bolt is machined to interface with thrust bearing 145 and swivel seal 132 as it passes through the lower pressure vessel head 130. The bearing bolt shaft extension continues below the pressure vessel head which interfaces with the brake mechanism and then proceeds to connect with the compression coupling of the motor 134. Torque reaction for motor 134 is provided through a flange mounting connection between the motor housing and the lower pressure vessel head 130. The motor is connected to a variable speed drive (VSD) 204 configured so that its rotation speed can be adjusted continuously. Referring to Figure 12, the VSD 204 can also reverse the motor rotation direction so that its torque and speed range can be effectively doubled. The screw can therefore be operated in the clockwise direction for the upstroke and in the counterclockwise direction for the downstroke.
    [0064] In the pressure vessel, the threaded portion of the bolt interfaces with a planetary bearing bolt nut assembly 122. The nut assembly 122 is fixedly secured to the lower segment of the impinging plunger 108 so that, as per the screw rotates in the clockwise direction, the striking plunger pressing moves upwards. Upon counterclockwise rotation, the striking plunger 108 moves downward. This is usually shown in Figures 10A and 10B. The impingement plunger 108 is held radially during its axial movement by guide bearings 147 (e.g. sealing bands) located in the annular area between the impingement plunger 108 and the guide tube 146. The guide tube 146 is situated surrounding coaxially the pressing tube 109 is statically mounted on the lower pressure head. It extends upward through the housing to slide into a recessed receiving hole feature in the upper pressure vessel head 150. Radial support is provided to the upper guide tube through a spacer ring between the guide tube and the walls of recessed hole of the top pressure vessel head.
    [0065] An anti-rotation mechanism 160 is required to prevent the impinging plunger 108 from rotating in conjunction with the torque provided by the bolt 118. The current disclosure calls for an anti-rotation clamp component 160' fixedly attached to a side portion 111 of the impinging plunger 108 and located so that it slides into a slot machined in the side wall of the guide tube 146. The interface between the anti-rotation clamp 160' and the guide tube 146 provides a restriction of rotation for the striking plunger 108 while still allowing free translation in the axial vertical direction.
    [0066] Lubrication is provided to moving parts within the mechanism by means of an electric oil pump 162 located on the upper surface of the lower pressure vessel head 130. The lower pressure vessel head 130 also serves as a collecting area where a filtered pump inlet is submerged, allowing clean oil to be circulated back through the pump and distribution system. The striker plunger, bolt, nut, and anti-rotation mechanism are all preferably lubricated from a point on top of the anti-rotation slot in the guide tube.
    [0067] Fixedly secured and sealed to the upper end of the striking piston is a wire rope drum and upper striker piston assembly. The two steel cable drums are attached to the ends of a shaft that passes laterally through a hole in the too section of the upper striker piston. The shaft is supported on radial bearings sealed inside the hole of the upper striker piston. A steel cable passes over the drums that rest in the grooves machined in its outer diameter. Wire rope attaches to anchors in the mounting base at the rear of the pressure vessel. On the front side of the pressure vessel, the steel cable is secured to a carrier bar which is, in turn, attached to the polished rod that extends from the wellhead. WORKING PRINCIPLE OF THE INVENTION
    [0068] The working principle of the invention is based on the transmission of linear motion and force through a planetary bearing screw mechanism. A motor can be coupled to the rotating element of a planetary bearing screw mechanism. Upon rotation in either direction clockwise or counterclockwise, the motor can translate the planetary bearing nut (and by connection, the striking piston pressing) along the length of the bolt member. The linear screw mechanism is augmented by an air spring counterbalance that is integrated into the rolling screw actuator mechanism. The air passages are strategically placed inside the guide tube, the pressing ram and the screw members so that the pressurized air has the ability to continuously migrate through the entire system and effect an imbalance of force in the protected area of the pressing ram. The effect is that of a relatively consistent lifting force and is exerted on the striker piston to deflect the average well load encountered by the pumping unit in addition to the weight of any upper component by the moving striker piston such as steel cable, conveyor bar, drums, shaft, bearings and the striking plunger assembly itself. The magnitude of the lifting force is a function of the pressure within the surrounding pressure vessel which varies primarily with the amount of compressible air contained therein.
    [0069] The amount of counterbalance force can be adjusted and controlled by adding or removing the mass of air from the containment vessel by activating a make-up air compressor or electrically actuated air compressor or purge valve respectively . Such offset adjustments can be made automatically upon command from a stem pump controller. By monitoring the motor torque (inferred from the motor current, for example), the peak magnitude upstroke and downstroke motor torque values can be compared and balanced by an error reduction computer algorithm recursive using these methods.
    [0070] A disclosure of the present invention is shown in Figure 10A and Figure 10B. This revelation is derived to produce a 254 cm (100 inches) stroke of polished rod. In this disclosure, the joint wire rope is anchored to a fixed location on the pumping unit frame at the rear of the pressure vessel. By running the wire rope over the drums mounted on top of the striking plunger pressing in the route for its connection to the carrier bar above the wellhead, a stroke of 254 cm (100 inches) of the polished rod can be affected with just 127 cm (50 inches) of striking plunger movement. This provides a desirable attribute in design compactness and relatively low speed operation of the linear actuation device. This proves to be beneficial in reducing speed-related wear on components such as seals, guides, etc. Consequently, the forces that need to be transmitted by the striking plunger are approximately double those at the wellhead.
    [0071] The permissible load diagram for the linear pumping unit invention is defined as:

    [0072] Note that the allowable load equation above includes inertia terms that are not typically reported for rocker arm balanced mass pumping units although their effects are certainly present on those machines as well. The mass of the rod pump, pump and fluid charges is characterized as being equivalent to
    and represents the volume of the acceleration inertia resistance ^αssy in this system. In contrast, the third inertia term, :/ , represents the internal inertia of the pumping unit invention and is very small in comparison. Neglected in this equation are rotational inertia terms primarily related to the screw and engine rotation elements, although these could be included if the circumstances and dynamics of the situation would benefit from such inclusion. Again, these terms are relatively small due to the small diameter (and thus small mass moment of inertia) of the screw. The general trend of the permissible load diagram for the pumping unit of the invention slopes slightly downward, moving from left to right due to the inherent variation in the counterbalance effect (changes in compressible volume) witnessed as the striker piston extends and retracts. The downward slope will tend to cause the current invention to show a slight preference for downhole applications that exhibit “overloaded stroke” characteristics of downhole pump plungers. This is illustrated broadly in Figure 11. PERMISSIBLE LOAD DIAGRAM COMPLIANCE
    [0073] Since the counterbalance effect (CBE) of the pumping unit is related to the air pressure acting on the striker piston and that the pressure will vary according to the volume of compressible air captured within the containment vessel, an improvement in the performance envelope of the current invention that is not generally available for other rod pumping unit designs arises. That is, a device and method for changing the slope of the pump unit's allowable load envelope to improve compliance to dynamometer load data. Such an exemplary device, in accordance with the present disclosure, is generally illustrated in Figure 12.
    [0074] As can be seen from the pump set 200 of Figure 12, the pump unit 201 of the invention described previously is augmented by an auxiliary pressure vessel 210 arranged to be in direct pressure and air flow communication with the primary pressure vessel 220 of the pumping unit. An incompressible fluid (such as a liquid-like oil or a similar oily fluid, gas or mixture of liquids or gases) occupies a portion of the internal volume of auxiliary pressure vessel 210 that is supplied from a storage vessel 208 under conditions of environment by means of a pump 207. Fluid can be transferred back and forth between auxiliary pressure vessel 210 and reservoir 208 by the aforementioned pump or by an electrically actuated valve 212, each controlled by the stem pump controller ( RPC). The purpose of the liquid is to displace a portion of the internal volume within the system 220 pressure vessel, thereby making the compressible volume a variable that can be controlled through automation. The addition of more liquid to pressure vessel 220 decreases the compressible volume contained within the system and vice versa. The pressure within the vessel system varies depending on the relationship as a polytropic process involving an ideal gas in which:
    P = the pressure within the vessel at a point of interest; P0 = the pressure within the vessel at a known condition such as at the bottom of the stroke; V0 = the compressible volume within the vessel at a known condition such as at the bottom of the stroke; V = the compressible volume within the vessel at a point of interest; e,k = the specific heat ratio of the gas in question (approximately 1.4 in the case of air; otherwise, usually a predetermined value).
    [0075] As will be understood, gases, particularly a natural gas, do not always have the same molecular composition and thus the specific heat ratio k may vary. AUTOMATICALLY CHANGE THE INCLINATION OF THE PUMP UNIT PERMISSIBLE LOAD ENVELOPE
    [0076] The above equation indicates that the pressure within the vessel system will drop as the compressible volume increases, as will occur as the pressing plunger of the pumping unit extends. The V0/V ratio also suggests that varying the overall compressible volume will alter the rate of pressure change as the striker plunger extends and retracts. This will have an effect on the degree of strength of the counterbalancing effect and will consequently change the permissible loading envelope of the pump unit. The diagram shown in Figure 13 illustrates changes in the slope of the allowable load diagram that results from an auxiliary pressure vessel partially filled with varying amounts of an incompressible liquid designed to control the amount of compressible volume remaining within the containment system.
    [0077] An automated system in which the rod pump controller reads measured well dynamometer data, compares this data to the permissible loading envelope of the pump unit in its present configuration, and then makes corrective commands to control the pump or the valve between the liquid reservoir and the auxiliary pressure vessel to raise or lower the liquid level in the vessel, has the potential to improve compliance and therefore improve the utilization and efficiency of the stem pump system. This improvement, along with an automated means to continuously maintain proper balance (keeping air pressure within proper limits), provides an improved means of adapting the pump unit system to changing well conditions and protecting system components. AUTOMATICALLY CORRECTING COUNTERBALANCE
    [0078] The practice of monitoring motor current (to infer torque) as a means of determining corrective action in relation to counterbalance adjustment has been used for many years in pump unit maintenance. However, due to the largely manual process of making physical adjustments (adding, removing or adjusting counterweights) to traditional rocker pump units, an automated method of corrective action was slow to materialize. Gas or pneumatic spring counterbalance offers an opportunity to make these balance corrections in a last-minute automated manner.
    [0079] Referring again to Figure 12 above, the pump unit motor of the current invention can be controlled and monitored by a variable speed drive (VSD) which, in turn, exchanges data with the stem pump controller (RPC). Motor torque or current can be monitored and peak magnitude upstroke and downstroke values compared to determine if the pump unit loading is balanced within acceptable limits. If the magnitude of upstroke torque is significantly greater than that of the downstroke, say, for example:
    then the unity falls short of balance. In this chaos, the RPC can activate the make-up air compressor to inject additional air mass into the pressure vessel system until the out-of-balance condition is relieved. If the opposite is detected, ie
    and the unit is above balance, the RPC can activate an electrically actuated bleed valve and draw air mass from the pressure vessel until proper balance is re-established. BASIC CONTROL SEQUENCE
    [0080] The example below, and shown schematically in Figure 19, illustrates a potential scenario where a stem pumping system of the present disclosure that incorporates the present invention pumping unit invention along with improvements to control counterbalance and tilt Permissible loading envelope is used to actively control the movement and/or force of the rod column, where the pump unit is characterized as having low inertia. In this scenario, the pump unit is initially put into service by interfacing with an application and is only roughly tuned to meet your optimization needs. By monitoring motor rotary position and torque or, alternatively, load and polished rod position, the rod pump controller (RPC) can derive a dynamometer data graph as illustrated generally in Figure 14.
    [0081] The linearized trend of dynamometer data can then be developed through linear regression methods such as “least squares”, or similar mathematical applications. The slope of this line can then be adopted as a target value for the slope of the unit's counterbalancing effect. The “y-intercept” of the return line, however, may not consistently reflect the “background dead center” counterbalancing effect required for equilibrium against peak and minimum loads. A corrected y-intercept can be computed by projecting a line averaging the minimum and peak loads along the slope from the regression analysis to the zero axis of the polished rod according to:

    [0082] With the target offset line effect (CBE) defined, a sequence of control steps can then be performed to affect the appropriate settings. The first of these is to set the maximum pressure within the system pressure vessel. The y-intercept at the target CBE line serves this purpose. The maximum pressure within the system will occur at the bottom of the striker piston stroke, which coincides with the zero position of the ground rod. Using the y-intercept value to calculate the maximum system pressure according to
    the rod pump controller (RPC) can compare measured peak pressure to the newly calculated “desired” peak pressure and either activate the system air compressor or electrically controlled purge valve to bring the system pressure within limits acceptable.
    [0083] Having adjusted the peak pressure in the system, the slope of the allowable load envelope of the pumping unit can be adjusted to match the slope of the estimated target counterbalance (ECB) by adding or removing liquid from the pressure vessel . The compressible volume required in the auxiliary tank to establish this slope can be calculated from
    where: Vb = Compressible volume in the primary pressure vessel at the bottom of the stroke. Wset = Weight of higher components such as wire rope, striking piston, drums, etc. sustained by counterbalance and screw forces.b = Target ECB line y-intercept (estimated counterbalance).Mreg = Target ECB line slope (estimated counterbalance).PRP = Poled rod position = Time interval to complete upstroke .Pmax = Maximum pressure in the containment vessel system. Occurs at the bottom of the stroke.doram = Outer diameter of striking piston tube pressing.diram = Inner diameter of striking piston tube pressing.Iram = extension of striking piston tube pressing.digt = Inner diameter of guide tube.htank = Vertical height of the cylindrical volume contained in the primary pressure vessel.dogt = Diameter of the outer side of the guide tube.dittanque = Diameter of the inner side of the pressure vessel housing.Dscrew = Thread pitch diameter of the bearing screw.dtb = Diameter of thrust bearing. Itb = Thrust bearing extension.Dnut = Bearing nut diameter.Inut = Bearing nut extension.yb = Inner face of striker piston location at bottom of stroke.SL = Polished rod stroke extension..
    [0084] Depending on the volume displaced of the actuator and other components within the primary pressure vessel, the volume of liquid required can be calculated by subtracting the amount above the total auxiliary vessel volume.
    [0085] Of course, as liquid is added to or removed from the system, the pressure within the vessel will vary somewhat inversely to the remaining compressible volume. The RPC (Stem Pump Controller) will continuously monitor and control the air pressure to keep it within limits when adding or removing liquid. ACTIVE PUMP UNIT SPEED CONTROL
    [0086] The work performed by the pumping unit in a cycle can be almost approximated by the area captured inside the dynamometer card according to:

    [0087] Even compatible with permissible load envelope slope and proper counterbalance, the dynamometer card produced in a rod pumping application is still very much a product of the movement and force interactions between the pumping unit, the bottom pump. well and the connecting pump rod column. The permissible loading diagram shown above may not yet particularly conform the well to the dynamometer card despite the counterbalance and CBE slope correction efforts. It should be noted, however, that the motion profile used to derive the above PLD quite simply comprised 2 periods of constant acceleration to increase or decrease the polished shank speed by approximately 30% of the cycle time interval. The remaining 70% of the cycle time interval is spent at constant speed. This explains the steps in allowable load near the top and bottom of the course. However, the duration of the increase and decrease of accelerations need not occur in a fixed time interval. They don't even need to be restricted as acceleration periods. The benefit of a low inertia pump unit mechanism such as that of the present invention is that speed changes can be made within a pump cycle without expending excessive amounts of energy. Slowly decreasing or increasing to a slightly higher polished rod speed can further allow one cycle to complete in the 6 seconds required to operate the machine at 10 SPM (strokes per minute).
    [0088] Velocity manipulation may have an effect on the shape of the dynamometer card as well. When comparing the dynamometer data to the allowable load diagram, if it is observed that the applied load deviates from the allowable load value so that the unit capacity is being underutilized, it can prove beneficial that the RPC commands a slight speed increase through that region. That is, as long as the speed boost doesn't trigger an issue such as rod fambagem or other problem. The predictive simulation capabilities of many rod pump controllers today allow test scenarios to be derived and modeled prior to deployment so that most issues can be avoided.
    [0089] The benefits of the systems and methods of the present invention are clear in view of the present disclosure. That is, the pump unit mechanism of the present invention combines a compressed gas or air spring for counterbalance with a linear bearing screw assembly to create and control the movements and lifting forces necessary to operate the downhole pump of a pumping unit. Additionally, the movement portions of the pump unit mechanism have relatively low mass and mass movements compared to traditional rocker unit designs and as such provide little inertia resistance to speed changes as needed for well optimization. With such low inertia, the motion profile of the striker piston can be varied quickly, using a controller well or the like, to reduce rod loading, improve working capacity utilization, improve pump filling, or mitigate drop issues. rod associated with heavy oil production.
    [0090] The pumping unit assembly of the present disclosure also achieves a low vertical height profile through a stroke extension multiplication method that involves drums employed at the end of the pressing ram and a steel cable anchored at a point on the ground fixed at one end, while being wound onto the pulleys and connected to the polished rod pit (via the carrier bar) on the opposite side. The environmental impact on the machine's site is therefore very slight. In other words, the current pump unit system is small in size compared to traditional rocker pump units with equivalent lifting capacity. The system additionally exhibits a generally 'monolithic' appearance with few observable moving parts, particularly at ground level, which results in a significant reduction in safety hazards, and may require little or no surveillance except around the wellhead.
    [0091] Additionally, as described in detail in this document, the counterbalance for the pumping unit system of the present invention is provided by a type of gas spring assembly, which offers numerous advantages over typical counterbalance unit based assemblies in bulk, including but not limited to allowing counterbalance adjustment automatically by controlling the gas pressure; allow a stem pump controller to monitor pump unit motor torque and provide balance pressure correction commands to a gas compressor or purge valve depending on the required optimization; and allow for a reduction in the weight and consumption of material related to the manufacture and transport of the pumping unit. Furthermore, since the stroke length of the pumping unit assembly described herein is not restricted by an extended geometry linkage system such as that seen in typical rocker-type pumping units, the stroke length can be adjusted. or varied in time. That is, downhole pump spacing can be monitored for evidence of gas blockage or marking, and corrections can be made automatically. System self-diagnostics such as valve checks can be readily performed automatically, too, through the integration of a stem pump controller.
    [0092] Yet another benefit of the pump unit systems and methods of use of the present invention is the ready application of adaptive noise cancellation. As is well understood in the art, the pump rod oscillates at a certain harmonic frequency during operation, resulting in rod fatigue issues directly associated with noise. With the pump unit system described here, one or more phase changes can be included, such as within the controller well, to attenuate and cancel the pump rod oscillation frequencies.
    [0093] Other and additional disclosures utilizing one or more aspects of the inventions described above may be derived without departing from the scope of Applicants' invention. For example, a series of auxiliary pressure vessels in fluid communication with each other can be used in a pumping unit in accordance with the present disclosure. Additionally, the various methods and disclosures of the manufacturing methods and system assembly, as well as location specifications, may be included in combination with each other to produce variations of the disclosed methods and disclosures. Discussion of singular elements can include plural elements and vice versa.
    [0094] The order of steps can occur in a variety of sequences unless specifically limited otherwise. The various steps described in this document can be combined with other steps, interspersed with the aforementioned steps and/or split into multiple steps. Similarly, elements have been functionally described and can be incorporated as separate components or can be combined into components that have multiple functions.
    [0095] The inventions have been described in the context of preferred disclosures and other disclosures and not every disclosure of the invention has been described. Obvious modifications and alterations to the disclosures described are available to those of ordinary skill in the technique. Disclosed and undisclosed disclosures are not intended to limit or restrict the scope or applicability of the invention conceived by the Applicants, but, in accordance with patent laws, the Applicants intend to fully protect all such modifications and enhancements that fall within the scope or equivalence range of the following claims.
    权利要求:
    Claims (9)
    [0001]
    1. DEVICE FOR ACTUATING A STEM of a pumping set with a pumping rod, characterized in that it comprises: a rod (24); a motor (134); a counterbalance set in communication with the motor (134), in which the set of counterbalance includes a pneumatic containment cylinder with the ability to change and maintain a counterbalance force by adding or removing a mass of fluid from the containment cylinder; and a linear actuator assembly operatively connected to the motor (134) and configured to provide a rod stroke (24), where the linear actuator assembly penetrates into upper and lower heads (150, 130) in the containment cylinder, where the linear actuator assembly is composed of a vertically oriented threaded bolt (118) and a planetary bearing nut (122), and wherein the motor (134) is configured to translate the planetary bearing nut (122) along the length of the threaded bolt. (118).
    [0002]
    2. DEVICE, according to claim 1, characterized in that a mass of air is added to or removed from the containment cylinder through the activation of a compensation air compressor or electrically actuated purge valve, respectively.
    [0003]
    3. DEVICE according to any one of claims 1 to 2, characterized in that the linear actuator assembly additionally comprises a pressing striking piston (108), in which the planetary bearing nut (122) is fixedly fastened to a lower segment of the piston pressing striker (108), such that the vertically oriented threaded screw (118) operates clockwise and counterclockwise, the pressing striker piston (108) operating upwardly and downwardly.
    [0004]
    4. DEVICE, according to claim 3, characterized in that the linear actuator assembly additionally comprises an anti-rotation mechanism (160) configured to prevent the impingement plunger (108) from rotating together with the torque provided by the screw (118) .
    [0005]
    5. DEVICE according to any one of claims 3 to 4, characterized in that the linear actuator assembly additionally comprises drums mounted on top of the pressing striker piston (108), and a steel cable that passes over the drums that rest in the slots machined in its external diameter.
    [0006]
    A device according to any one of claims 3 to 5, characterized in that the counterbalance assembly comprises air passages which are placed in such a way that the pressurized air effects a force imbalance in the protected area of the pressing striking piston (108).
    [0007]
    A device according to any one of claims 1 to 6, characterized in that it comprises a controller for adjusting the amount of counterbalancing force by adding or removing fluid mass from the containment cylinder.
    [0008]
    8. DEVICE, according to any one of claims 1 to 7, characterized in that the speed of the motor (134) is controlled as a signal control function from a controller (40).
    [0009]
    9. METHOD OF PUMPING A FLUID, which uses a pumping set with a pumping rod, characterized in that the pumping set with a pumping rod comprises the device, as defined in any one of claims 1 to 8, the method comprising: positioning the pumping assembly with a pump rod so that the pump comes into contact with a fluid reservoir; position the linear actuator assembly of the device so that its geometric axis of operation is the same as the geometric axis of movement of the pump rod ; providing a device counterbalance assembly including at least one pneumatic pressure vessel positioned so that it automatically relieves the load imposed on the motor (134) by the pump rod and the column of fluid to be pumped; and operate the motor (134) so that the pump acquires fluid in its downward stroke and transports fluid in its upward stroke, wherein at least one pneumatic pressure vessel contains an incompressible substance with the ability to communicate fluid between a separate reservoir and the pressure vessel.
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    同族专利:
    公开号 | 公开日
    BR112014010986A2|2017-06-06|
    US9115574B2|2015-08-25|
    US20130306326A1|2013-11-21|
    CN104136778B|2018-01-02|
    EP2776715B1|2020-01-22|
    US10422205B2|2019-09-24|
    WO2013070979A2|2013-05-16|
    CN104136778A|2014-11-05|
    US20160131128A1|2016-05-12|
    CA2854557A1|2013-05-16|
    CA2854557C|2020-06-02|
    EP2776715A2|2014-09-17|
    WO2013070979A3|2013-07-04|
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    法律状态:
    2018-12-04| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2020-02-11| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
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    申请号 | 申请日 | 专利标题
    US201161557269P| true| 2011-11-08|2011-11-08|
    US61/557,269|2011-11-08|
    PCT/US2012/064242|WO2013070979A2|2011-11-08|2012-11-08|Low profile rod pumping unit with pneumatic counterbalance for the active control of the rod string|
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