RU2611126C1 - Drive of oil well pump - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: invention relates to devices for fluid lifting from wells for use in oil industry for oil production. The drive comprises a motor, a gearbox, a mechanism converting rotation to reciprocating movement. Axles of the converting mechanism, counterweight and flexible link are near one vertical plane. A top driven sheave is installed in a housing with possibility of rotation and limited movement along axle of the converting mechanism to regulate tension of the continuous flexible link using a tensioner. The mechanism comprises a movable housing with axle of sheave installed on longitudinal carriers of the drive housing and connected with a pusher. The pusher is made in form of screw jack comprising jack bases connected by hinges in form of a rhomb. Opposite corners of the rhomb are made with possibility of approach or separation under action of a screw pair. One base of jack is fixed relatively to the housing, another base is fixed relatively to the movable housing. Screw of the screw pair is connected with motor drive to move the jack base with movable part of the tensioner upon tension decreasing of the flexible link below selected value of tension force of the flexible link. It comprises a load sensor functionally linked with a control unit.

EFFECT: drive of oil well pump automatically maintaining permanent tension of the flexible link of the converting mechanism with remote testing of its operation, and excludes effect of ultimate moment on the tensioner operability.

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Description

The invention relates to technical means for lifting liquid from wells and can be used in the oil industry for oil production by sucker rod pumps.

A well-known drive of a sucker-rod pump (patent RU No. 2200876, IPC F04B 47/02, publ. March 20, 2003, bull. No. 8), comprising a motor mounted on the base and placed on it, a mechanism for converting rotational motion into reciprocating, including a drive pulley and a curved guide element with a constant radius of curvature, covered by a flexible continuous link connected to a carriage connected to a counterweight installed in the guides and connected through a flexible link with a rod string, while the counterweight is made one, consisting of the main counterweight, normalizing the operation of the pump drive, equipped with rods of the minimum cross section and lowered to the minimum depth of the well, and additional counterweights made with the possibility of placing their mass symmetrically with respect to the axis of symmetry of the plane of the continuous continuous link on the main counterweight, with the total center of gravity located in close proximity to this plane, and the flexible link connecting the counterweight to the rod string is placed with the formation of an even number of steam of the branch branches, the nodes of the connection of the branches of the flexible link with the counterweight are placed pairwise symmetrically with respect to the axis of symmetry of the flexible link outside its contour, while the nodes of the connection of the flexible link with the counterweight and the suspension node of the rods are made to ensure the same tension of all branches of the flexible link, and the frame is equipped with wheels and an additional drive and is made with the possibility of fixing relative to the base in any positions, and the wheels are installed with the possibility of interaction with the guides, and an additional frame, United with the main frame with the ability to move in the direction of the axis of symmetry of the contour of a flexible continuous link passing through the leading and curved guide element of the transforming mechanism, the connection being made with the possibility of fixing the additional frame relative to the main frame in any position, while the flexible link connecting the counterweight to the rod string is closed.

A well-known drive of a sucker-rod pump (US patent No. 4916959, Int. Cl. 4 B66B 5/26, publ. 04/17/1990), containing installed on the basis of a single frame with a housing engine, a mechanism that converts rotational motion into reciprocating, including drive and driven pulleys covered by a continuous flexible link connected to a carriage connected to a counterweight mounted in the guides of the housing and connected through a flexible link to the rod suspension unit, the axes of the conversion mechanism, the counterweight and the flexible link being close to second vertical plane, and the top (driven) pulley mounted in the housing rotatably and axially limited movement converting mechanism for adjusting the tension of a continuous flexible member.

However, known devices have the following disadvantages:

- firstly, the tension of the continuous flexible link is regulated periodically with the participation of staff, which leads to the formation of sagging (weakening) of the flexible link between the adjustments, which causes dynamic loads in the conversion mechanism, reducing the service life of the flexible link and the entire installation or leading to more frequent tension control, which significantly increases maintenance costs;

- secondly, for optimal tension of the flexible link for maintenance personnel, it is necessary to determine the magnitude of the tension using special devices and devices, which leads to additional investments;

- thirdly, to regulate the tension of the flexible link by maintenance personnel, it is necessary to stop the drive, which leads to losses of the products being produced, as well as the cost of working time of the maintenance personnel;

- fourthly, the maintenance personnel adjust the tension of the flexible link when the counterweight is located on the technological stops with the possibility of subsequent lifting of the counterweight for removal from the stops, which leads to excessive tension of one section of the flexible link with insufficient tension of the other and is the reason for its premature failure.

The closest in technical essence is the drive of a borehole sucker rod pump (patent RU No. 2522729, IPC F04B 47/02, publ. 07/20/2014, bull. No. 20), containing mounted on the base frame with the body of the motor, gearbox, rotary converting mechanism reciprocating movement, including driving and driven pulleys, covered by a continuous flexible link connected to a carriage connected to a counterweight mounted in the guides of the housing and connected through a flexible link to the rod suspension unit, and the axis of the converting mechanism , the counterweight and the flexible link are close to one vertical plane, and the upper (driven) pulley is mounted in the housing with the possibility of rotation and limited movement along the axis of the converting mechanism for adjusting the tension of the continuous flexible link using a tensioning mechanism consisting of a movable housing with the axis of the pulley mounted on the longitudinal slides of the housing and connected to the pusher, made in the form of a screw pair, the nut of which is rigidly connected to the housing, and an anti-reversal mechanism, moreover tivootvorotny mechanism is in the form of an automatic mechanism, and the screw is provided with a pair of helical drum wound with a flexible link, through which the end block is connected to the load, arranged to rotate the drum for a pair of helical tension continuous flexible link when loosening and moving down the carriage with a counterweight.

The disadvantages of the known solutions are:

- firstly, the impossibility of diagnosing the operation of the transforming drive mechanism (monitoring the wear of the flexible link, monitoring the operation of the tension mechanism, determining the force in the flexible link, etc.) remotely without coming to the well;

- secondly, the need to take measures to overcome the moment of breaking in the screw pair at the beginning of rotation of the screw, i.e. the weight of the load selected for the automatic operation of the tensioning mechanism, under certain circumstances, for example, when the lubricant solidifies due to temperature differences, contact of the lubricant with the external environment (dust, mechanical impurities, etc.) or due to prolonged shutdown of the drive, etc., may not enough to turn the screw at the initial moment of its movement, which will lead to unsatisfactory operation of the tensioning mechanism.

The technical objectives of the invention are the automatic maintenance of constant tension of the flexible link of the converting mechanism with remote diagnosis of its operation, as well as eliminating the influence of the breakaway moment on the operability of the tensioning mechanism.

The stated technical problems are solved by a borehole sucker-rod pump drive, comprising an engine, a gearbox, a mechanism that converts rotational motion into reciprocating, including a driving and driven pulleys covered by a continuous flexible link associated with a carriage connected to a counterweight, mounted on a base on a frame with a housing, installed in the guides of the housing and connected through a flexible link with the node suspension rods, and the axis of the converting mechanism, the counterweight and the flexible link are close to one Vertical, plane, and the upper driven pulley mounted in the housing rotatably and limited movement along adjustment axis converting mechanism for tensioning the continuous flexible link by means of the tensioning mechanism comprised of the movable housing with pulley axle mounted on the longitudinal slide actuator housing and connected with the pusher.

New is that the pusher of the tensioning mechanism is made in the form of a diamond-shaped screw jack, consisting of the base of the jack connected by hinges in the form of a rhombus, the opposite corners of which are made with the possibility of rapprochement or divergence under the action of a screw pair, with one base of the jack fixed relative to the housing and the other the base of the jack is relative to the movable housing of the tensioning mechanism, while the screw of the screw pair of the jack is connected to an electric drive that allows the base to be moved to jack with the movable part of the tension mechanism when the tension of the flexible link is weakened below the selected value of the tension force of the flexible link, determined by the load sensor, which is functionally connected to the control unit.

In FIG. 1 schematically depicts a borehole sucker rod pump drive (side view); in FIG. 2 is the same, view A of FIG. 1 (frame 2, engine 4 and gear 5 not shown); in FIG. 3 is a diagram of a drive tension mechanism located above a movable housing (section BB in FIG. 2); in FIG. 4 is a diagram of a drive tension mechanism when located under a movable housing (section BB in FIG. 2).

A downhole sucker-rod pump drive, comprising an engine 4, a gearbox 5, a mechanism that converts rotational motion into reciprocating, including a leading 6 (Fig. 2) and driven 7 pulleys, mounted on the base 1 (Fig. 1) on the frame 2 with the casing 3, for example, sprockets, or toothed pulleys, or the like, covered by a continuous flexible link 8, for example, a chain, or toothed belt, or the like, associated with a carriage 9 connected to a counterweight 10 mounted in the guides 11 of the housing 3 ( Fig. 1) and connected through a flexible link 12, for example conveyor linen y, or a rope, or the like, with a suspension assembly of the rods 13, the axis 14 of the converting mechanism, the axis 15 of the counterweight 10 and the axis 16 of the flexible link 12 are located near one vertical plane 17, and the upper (driven) pulley 7 (Fig. 2) is installed in the housing 3 (Fig. 1) with the possibility of rotation and limited movement along the axis 14 of the converting mechanism for regulating the tension of the continuous flexible link 8 (Fig. 3) using a tensioning mechanism consisting of a movable housing 18 with the axis 19 of the pulley 7, mounted on the longitudinal slide 20 of the drive housing 3 and the connection Nogo tappet 21. The energy source for the motor 4 may be an electrical energy, while as the motor is an electric motor, or the energy of the burning fuel (internal combustion engine), or another type of energy and the corresponding motor.

The pusher 21 of the tensioning mechanism is made in the form of a diamond-shaped screw jack 22, consisting of the bases 23 and 24 of the jack 22 connected by hinges 25 in the form of a rhombus, the opposite angles 26 and 27 of which are made with the possibility of divergence under the action of the screw pair 28, and one base 23 of the jack 22 fixed relative to the housing 3, and the other base 24 of the jack 22 is relative to the movable housing 18 of the tensioning mechanism, while the screw 29 of the screw pair 28 of the jack 22 is connected to an electric drive 30, allowing the base 24 to be moved up to jack 22 with the movable part of the tensioning mechanism when the tension of the flexible link 8 is weakened below the selected value of the tension force of the flexible link 8 determined by the load sensor 31, which is functionally connected to the control unit (not shown).

The electric drive 30 may consist only of an electric motor, as in FIG. 3, or an electric motor with a transmission, which can be mechanical (gear, belt, etc.), hydraulic or other, or another drive, the energy source of which is electric energy.

As the load sensor 31, known sensor designs can be used, for example, a sensor that determines the force on the basis of the 24 jacks 22, as in FIG. 3, or a sensor of the tension force of the flexible link 8 (not shown) or a sensor of any other type mounted both on the electric motor and on any other element of the conversion mechanism, as well as a combination of various types of sensors. For the design of the load cell 31 authors do not claim.

The control unit may be integrated in the load sensor 31, for example, in the form of a limit switch (not shown) or may be in the form of a separate unit located on the drive, for example, at a control station (not shown) of the drive motor 4, or located at a distance, for example at the control room (not shown in the figures).

The operation of the device is as follows.

Near the wellhead is installed base 1 (Fig. 1) of the drive. The base 1 can be made in the form of a foundation plate in the case of stationary placement of the drive or sleigh (not shown) - in the case of a mobile (mobile) version of the drive. On the basis of 1 mounted drive assembly. The column of the rods of the installation of a downhole sucker rod pump (not shown) is suspended on the suspension unit of the rods 13 of the drive.

After turning on the motor 4 (Fig. 1), the rotation through the gear 5 and the drive pulley 6 (Fig. 2) of the converting mechanism is transmitted to a continuously closed flexible link 8. Suppose the flexible link 8 moves counterclockwise. The carriage 9 connected to the flexible link 8, connected to the counterweight 10 equipped with wheels 32, moves down the guides 11 of the housing 3 (Fig. 1), and connected to the counterweight 10 (Fig. 2) through the flexible link 12 (Fig. 1) node the suspension of the rods 13 rises, respectively raising the column of rods with the plunger of the downhole sucker rod pump (shown). When the carriage 9 (Fig. 2) reaches the transforming mechanism to its lowest position, the counterweight 10 moves from the downstroke to the upstroke due to the transition of the carriage 9, equipped with wheels 33, along the guides 34 from one branch of the flexible link 8 to another - the rotation movement is converted the driving pulley 6 in the reciprocating counterweight 10. Accordingly, when this happens, the direction of movement of the suspension unit of the rods 13 (Fig. 1) changes from up to down. The same thing happens when the carriage 9 (Fig. 2) passes through the extreme upper position — only from the downward stroke to the upward travel of the rod suspension unit 13 (Fig. 1).

To reduce the loads on the elements of the converting mechanism, in particular on the flexible link 8 (Fig. 2), the axis 14 (Fig. 1) of the converting mechanism, 15 counterweights 10 and 16 of the flexible link 12 are located near one vertical plane 17.

The frame 2 (Fig. 1) can be rigidly attached to the housing 3 or can be adjusted (not shown) relative to the housing 3 depending on the manufacturability requirements of the drive assembly.

During operation of the drive, the flexible link 8 (Fig. 2) will be lengthened by cyclic loading and due to wear, therefore, in the drive design, to automatically eliminate the influence of the human factor and maintain constant tension of the flexible link 8, a mechanism for automatically tensioning the flexible link 8 by moving the upper (driven ) a pulley 7 along the axis 14 (Fig. 1) of the converting mechanism using the tensioning mechanism as the flexible link 8 is weakened (Fig. 2).

The principle of operation of the tensioning mechanism is as follows. When the carriage 9 (Fig. 2) passes through the lowest position, the entire flexible link 8 is tensioned, i.e. the flexible link 8 is fully uniformly loaded by pulling force from the lower (leading) pulley 6. As the carriage 9 moves with the counterweight 10 upward, the loaded portion of the flexible link 8 decreases from the maximum, full length of the closed flexible link 8, after the carriage 9 passes through the lowest position, to the minimum length when approaching the carriage 9 to the lowest position after the downward movement following the upward movement of the carriage 9 with the counterweight 10. The unloaded portion of the flexible link 8 is relaxed. While the carriage 9 with the counterweight 10 is in the straight section of the downward stroke, the larger portion of the flexible link 8 is weakened. The tension in this section will be more effective than in the other positions of the carriage 9 with the counterweight 10, since the different pulley 7 acts on the upper pulley up and down travel of the counterweight 10, characterized by the magnitude of the force acting on the weight of the counterweight 10, i.e. when moving down on the upper pulley assembly 7, the load from the weight of the counterweight 10 does not work. For example, on the drive of the borehole sucker rod pump ПЦ 60-3-0,5 / 2,5 produced by the Bugulma Mechanical Plant, the load on the tension mechanism will be about 76500 N when the counterweight is up, and 3950 N when the down stroke is on. The tension mechanism works exactly in this section of the counterbalance 10 downward stroke, if the counterbalance 10 were actuated in other positions, a much greater force would be required on the follower 21 of the tensioning mechanism, which would lead to excessive tension of the flexible link 8 in the straight section of the counterbalance downward travel 10. The flexible link about 8 (Fig. 2), the authors consider optimally stretched when it is located on the pulleys 6 and 7 without sagging, i.e. the tension force of the flexible link 8 is selected to exceed the total weight of the movable housing 18 with the axis 19 and the sprocket 7 and the relaxed part of the flexible link 8 by the amount of force sufficient to prevent sagging of the flexible link 8, determined experimentally. The load sensor 31 (Fig. 3) before starting up the drive is adjusted to the selected tension force. The tensioning mechanism will work when the actual load recorded by the load sensor 31 is reduced below the selected force value: at the command of the control unit, the electric drive 30 is automatically turned on, which, rotating the screw 29 of the screw pair 28, spreads opposite angles 26 and 27, connected by hinges 25 in the form of a rhombus, and thereby raises the base 24 of the jack 22 and the movable housing 18 of the tensioning mechanism rigidly connected to it, which leads to the tension of the flexible link 8 to the selected amount of force, after which the electric drive 30 at the command of the unit The pressure is switched off until the next loss.

When two tension sensors (not shown) installed on different branches of the flexible link 8 are used as a load sensor 31, the control unit, when the sensor readings diverge, gives a command to turn on the electric drive 30, which equalizes the forces, after which it is turned off by a command from the control unit next command to enable.

Based on the foregoing, the torque created by the rotation mechanism 29 (Fig. 3) on the screw 28 is calculated so that the force on the pusher 21 is not less than the effort to raise the total weight of the movable housing 18 with the axis 19 and the sprocket 7 and the relaxed part of the flexible link 8, and also to overcome friction losses in the nodes of the tensioning mechanism and in the slide 20. For the above-mentioned example of the PC 60-3-0.5 / 2.5 drive, the total weight is about 3950 N without taking into account losses in the tensioning mechanism. When using a diamond-shaped jack in the most favorable range of its operation, in which the force on the screw 29 is less than the lifted weight and the necessary course of tension is ensured, we obtain the necessary maximum torque of about 7 N⋅m.

The stroke of the movable housing 18 (the tension stroke) is limited and is selected on the basis of the necessary and sufficient range of tension control of the flexible link 8 (Fig. 2), determined on the basis of the operating conditions and operating experience of the flexible link 8 used in the drive. The proposed tension mechanism allows you to adjust the stroke of the movable housing 18 for the entire service life of the flexible link 8. For example, if a chain is used as the flexible link 8, the elongation limit, respectively, and the service life of the chain are two steps, i.e. for an example of a PC 60-3-0.5 / 2.5 drive with a 2PR-50.8-453.6 chain, the elongation limit corresponds to a value of 101.6 mm, after which it is necessary to repair or replace the chain. This extension of the chain corresponds to the stroke of the movable housing 18 (Fig. 3) along the axis 14 (Fig. 1) of the 50.8 mm converting mechanism with a drive stroke of 3 m and a pitch diameter of sprockets 6 and 7 (Fig. 2) equal to 244.33 mm

The electric drive 30 will mainly operate in a short-term mode: short-term start and relatively long stop, in which the quality of electric motors will be used in the form of a multiple excess of the starting torque over the nominal, usually about 2 times. In the nominal mode, the electric drive 30 will only work if the flexible link 8 is pretensioned and the tension mechanism is removed to remove the flexible link 8. The power of the electric drive 30 is selected for the nominal mode. For the case under consideration with a PC 60-3-0.5 / 2.5 drive, it is sufficient to use an electric drive 30 with a rated speed of the electric motor of 750 min ^-1 and a power of 1.5 kW in the tensioning mechanism, and when using an electric motor 30 with a nominal the rotational speed of the electric motor is 1500 min ^-1 with a planetary gear with a gear ratio, for example, 8 the electric motor power will be 0.5 kW. The use of a low-power electric motor and its short-term operation slightly increases the total energy consumption of the drive. For comparison, in the above example, an electric motor with a power of 5.5 kW is used as the main engine 4 (Fig. 1).

The slide 20 (Fig. 1) allows the housing 18 (Fig. 3) of the tensioning mechanism to move only along the axis 14 (Fig. 1) of the conversion mechanism.

After the running of the movable housing 18 has been exhausted (Fig. 3), the drive stops and the control unit (not shown) issues relevant information about the need to replace the flexible link 8, which will eliminate the breakdown of the drive that may occur when the flexible link 8 is broken.

The proposed technical solution allows you, automatically, without the participation of maintenance personnel and stopping the drive, to maintain a continuous flexible link 8 of the transforming drive mechanism in optimal condition - without sagging and hauling, so the labor and maintenance costs of the drive will be reduced.

If the flexible link 8 is stretched (in the drive without a tensioning mechanism), then at the moment the carriage 9 passes through the lowest position (the drive pulley 6 rotates at a constant speed), the relaxed unloaded portion of the closed flexible link 8 is tensioned due to the rotation of the driven pulley 7 with the axis 19 in the housing 18, accompanied by a slowdown of the carriage 9, moving by inertia, and subsequent impact, leading to additional shock loads in the operation of the drive and installation of the borehole sucker rod pump as a whole, many times greater than the calculation ny dynamic loads. The magnitude of the impact depends on the sag of the flexible link 8 - the more the sag, the stronger the impact. Automatic maintenance of constant tension of the flexible link 8 in the proposed design will avoid unnecessary loads, which will increase the service life of the flexible link 8 and the drive as a whole, as well as reduce shock loads on the downhole equipment of the borehole sucker pump installation.

When the control unit is located as a separate unit at the control room (not shown) or in the control station (not shown) by the drive according to the load sensor 31, it is possible to additionally obtain data on load changes over time and the counterweight 10 stroke cycle, change the amount of flexible tension link 8, the dynamics of wear and the need to replace the flexible link 8 and other parameters that allow real-time monitoring of the operation of the main element of the drive - the transforming mechanism - and predict the timing of SIC actuator maintenance, resulting in substantial savings in servicing of drives in comparison with the service via a fixed period of calendar time.

To remove the flexible link 8 from the pulleys 6 and 7, for example, to replace it or to replace the pulleys 6 and / or 7, or for other purposes, it is necessary to switch the tension mechanism through the control unit of the electric drive 30 to reverse rotation, while the movable part the pusher 21, respectively, and the movable housing 18 of the drive with the axis 19 and the pulley 7, will go down, loosening the flexible link 8. Upon reaching the position of the pulley 7, at which it is possible to remove the flexible link 8 from the pulley 7, the electric drive 8 is manually turned off.

Using a diamond-shaped screw jack 22 allows to reduce the diameter of the screw 29 of the screw pair 28, which is determined from the condition of stability from the action on the base 24 of the total weight of the movable housing 18 with the axis 19 and the sprocket 7, the flexible link 8 and the counterweight 10, which allows to reduce the moment of breaking compared to a prototype, and in conjunction with the use of an electric drive 30 with a multiple excess of the starting torque over the nominal one, eliminates the influence of the breaking moment on the operability of the tensioning mechanism.

The proposed device similarly works when the tension mechanism is located under the upper (driven) pulley 7 (Fig. 2). The difference in this arrangement is that the base 23 (Fig. 4) of the jack 22 will be located at the bottom, and the base 24 at the top, and the opposite angles 26 and 27 of the tensioning mechanism for tensioning the flexible link 8 (Fig. 2) will not diverge, but get close.

Thanks to the use of the proposed device, the constant tension of the flexible link of the transforming mechanism with remote diagnosis of its operation is automatically maintained, and the influence of the breakaway moment on the operability of the tension mechanism is eliminated.

Claims (1)

A borehole sucker-rod pump drive, comprising an engine, a gearbox, a mechanism that converts rotational motion into a reciprocating drive, mounted on a base with a frame, and includes a driving and driven pulleys covered by a continuous flexible link associated with a carriage connected to a counterweight mounted in the guides of the housing and connected through a flexible link with the node suspension rods, and the axis of the converting mechanism, the counterweight and the flexible link are close to one vertical plane, and the upper driven shk in installed in the housing with the possibility of rotation and limited movement along the axis of the converting mechanism for adjusting the tension of the continuous flexible link using a tensioning mechanism consisting of a movable housing with a pulley axis mounted on the longitudinal slides of the drive housing and connected to the pusher, characterized in that the tensioner pusher the mechanism is made in the form of a diamond-shaped screw jack, consisting of the base of the jack, connected by hinges in the form of a rhombus, the opposite angles of which are made with the possibility of rapprochement or divergence under the influence of a screw pair, moreover, one jack base is fixed relative to the housing, and the other jack base is relative to the movable housing of the tensioning mechanism, while the screw of the screw pair of the jack is connected to an electric drive that allows the jack base to be moved with the movable part of the tensioning mechanism when the weakening of the tension of the flexible link below the selected value of the tension force of the flexible link defined by the load sensor, which is functionally connected with th control.

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