RU2530976C2 - Pump of rod type for production of high-viscosity sand oil (versions) - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention relates to oil production, namely, to production of high-viscosity sand oil, and may be used to produce any formation fluid from directional and horizontal wells. The pump comprises a cylinder with a plunger placed in it and with a suction ball valve. The plunger has a hollow bushing and a valve carriage with an injection ball valve. The valve carriage is connected to a sucker rod string and a hollow bushing. The plunger is equipped with compression rings, a slide mechanism for forced closure of the injection valve. The slide mechanism comprises a slider and a pusher. The slider interacts with an inner wall of the cylinder, and the pusher - with an injection valve. The hollow bushing of the plunger is equipped with a spring, which interacts with compression rings. At the lower ends of the cylinder and the plunger there are permanent magnets. The lower end of the hollow bushing is made in the form of a cone with a circular sharp edge, and on the upper end of the valve carriage there are wedge-shaped scraper edges. The slider of the slide mechanism is equipped with friction rings or plates. The rod pump may be made with a rubber bushing placed on the hollow bushing of the plunger. The rod pump may be made with a plunger, equipped with a spiral compression spring interacting with the inner wall of the pump cylinder.

EFFECT: increased reliability and durability of operation, increased coefficient of filling and supply by exclusion of failure in operation of an injection ball valve.

3 cl, 7 dwg

Description

The invention relates to the oil industry, namely the production of highly viscous sand oil and can be used for the production of any formation fluid.

Known sucker-rod pumps with forced opening and closing of the discharge valve from the movement of the string of pump rods (AS USSR No. 987175, F04B 42/02; AS USSR No. 1675577, F04B 42/02; Patent RU 2213261 C1, 09/27/2003 ; US Patent No. 5,407,333, F04B 47/00).

The disadvantage of these devices is the complexity of the structures, low wear resistance, a plunger spline during oil production with sand content.

A device designed for pumping highly viscous oil with mechanical impurities, containing a cylinder with a suction ball valve, a plunger with a hollow sleeve and compression rings, a valve carriage with a pressure ball valve connected to a hollow sleeve and a rod string, was selected as an analogue (see RU 90143 U1 12/27/2009).

The disadvantage of an analogue, like other known devices, is the complexity of the design and its assembly, low wear resistance and durability. The main disadvantage of the analogue is the plug of the plunger during oil production with sand content.

These disadvantages of the analogue are eliminated in the claimed invention.

The objective and technical result of the invention is the development and creation of a workable design and a highly efficient, reliable pump for the production of highly viscous oil with a high sand content.

To solve the problem and achieve a technical result in the design of a sucker rod pump for the production of highly viscous sand oil, comprising a cylinder with a suction ball valve, a plunger with a hollow sleeve and compression rings, a valve carriage with a discharge ball valve connected to a hollow sleeve and a rod string, according to the invention the plunger is equipped with a spool mechanism, which consists of a slide and a pusher. The slider interacts with the cylinder wall, and the pusher interacts with the ball of the discharge valve. In addition, the plunger is equipped with a spring mounted on the hollow sleeve and interacting with the inner surface of the compression rings. In this case, the outer diameter of the spring is made larger than the inner diameter of the compression rings. In addition, the cylinder and plunger of the pump are equipped with permanent magnets. They are located on the lower ends of the cylinder and plunger bush. The lower end of the plunger sleeve is made with a surface in the form of a cone with an annular sharp edge. At the upper end of the valve carriage, wedge-shaped scraper edges are made. The slide of the spool mechanism is provided with friction rings or friction plates.

According to the second embodiment, the plunger of the sucker rod pump is equipped with a rubber sleeve and provides for the execution of the rubber sleeve of the plunger with a protrusion made along a helical line that interacts with the inner surface of the compression rings.

According to the third embodiment, the plunger of the sucker rod pump is equipped with a compression unit containing a spiral compression spring and o-rings. The spiral compression spring interacts with the inner wall of the cylinder. The lower end of the spiral compression spring is fixed to the hollow sleeve of the plunger, and its upper end is made with the possibility of axial movement. Moreover, its outer diameter is made larger than the inner diameter of the cylinder sleeve. O-rings are installed between the hollow sleeve of the plunger and the spiral compression spring. In addition, the spiral compression spring can be made in the form of two or more spiral springs interacting with the inner wall of the cylinder and rubber rings.

Justification of some distinguishing features

In the proposed device, in contrast to the prototype, the plunger is equipped with a spool mechanism, which consists of a slider interacting with the inner wall of the cylinder and a pusher interacting with the ball of the discharge valve. The spool mechanism serves to force the closing of the discharge valve. The force required to close the ball valve is provided by the frictional force between the slider and the cylinder.

In addition, the plunger is equipped with a spring mounted on the hollow sleeve and interacting with the inner surface of the compression rings. The spring is used for contacting (pressing) the compression rings to the working (inner) surface of the cylinder. Moreover, each ring under a certain sector, depending on the spring pitch, is pressed against the cylinder wall. As the friction surfaces of the rings and the cylinder wear, the spring will press the rings against the surface of the cylinder, ensuring the tightness of the rubbing pairs. This completely eliminates the leakage between the plunger and the cylinder.

Permanent magnets are installed at the lower ends (at the inlet) of the cylinder and plunger. This is due to the fact that magnetic field lines decrease the hydrogen bond between hydrocarbon molecules. This leads to a decrease in the viscosity of the produced oil in the zone of operation of the valve pair. In addition, the magnetic field helps to reduce paraffin-resinous deposits.

The lower end of the plunger sleeve is made with a surface in the form of a cone with an annular sharp edge. This form of the sleeve helps remove sand from the viscous sublayer of the wall zone of the cylinder. Thus, sand oil from the wall zone of the cylinder enters the stream and prevents sand from entering the gap between the plunger and the cylinder during the plunger “down”.

At the upper end of the valve carriage, wedge-shaped scraper edges are made. This is due to the fact that when the plunger moves up, the wedge-shaped scraper edges remove sand from the wall zone of the cylinder and prevent them from falling into the gap between the plunger and the cylinder when the plunger moves up.

According to the second option, the plunger is equipped with a rubber sleeve made with a protrusion along a helical line. This is due to the fact that the rubber protrusion, made along a helical line, interacts with the inner surface of the compression rings. Moreover, each compression ring under a certain sector, depending on the pitch of the screw protrusion, is pressed against the cylinder wall, ensuring the tightness of the gap between the plunger and the cylinder.

According to the third option, the plunger is equipped with a compression unit containing a spiral compression spring, the outer diameter of which is larger than the inner diameter of the cylinder and the o-rings. This technical solution provides reliable tightness between the plunger and the pump cylinder, even during operation with large diametrical wear of their rubbing surfaces. This is achieved due to the increased diameter of the compression spring and the elasticity of its spiral turns.

O-rings installed between the hollow plug of the plunger and the compression spring ensure reliable tightness between them and prevent leakage between the spiral turns.

The implementation of the compression spring in the form of two or more coil springs due to the manufacturability of their manufacture and repair, because during operation, the upper part of the compression unit is subjected to intense wear.

All the distinguishing features given in the technical solution serve to accomplish the task and achieve the technical result by increasing the reliability and durability of the sucker rod pump in difficult conditions with a high content of solids, sand, paraffin deposits, high oil viscosity, with a large gas factor and in directional wells.

The invention is illustrated by the figures.

In Fig.1 shows a General view of a rod pump in section; figure 2 shows a wedge-shaped scraper edge made on the upper end of the valve carriage; figure 3 shows the sucker rod pump during the stroke of the plunger up; figure 4 is a section aa in figure 3; figure 5 shows the sucker rod pump during the stroke of the plunger down; figure 6 - the second version of the plunger, equipped with a rubber sleeve made with a protrusion along a helical line; Fig.7 is a third variant of the plunger equipped with a compression unit made in the form of a spiral spring.

The sucker rod pump for the production of highly viscous sand oil (Fig. 1) contains a cylinder 1 with a plunger 2 located in it and with a suction ball valve 3. The plunger 2 has a hollow sleeve 4 and a valve carriage 5 with a pressure ball valve 6. The valve carriage 5 is connected to the column the sucker rods 7 and the hollow sleeve 4. The plunger 2 is equipped with compression rings 8, the spool mechanism 9. The spool mechanism 9 consists of a slider 10 and a pusher 11. The slider 10 interacts with the inner wall of the cylinder 1, and the pusher 11 interacts with the discharge ball valve 6. The hollow sleeve 4 is equipped with a spring 12. The spring 12 interacts with the inner surface of the compression rings 8. At the lower ends of the cylinder 1 and the hollow sleeve 4 are placed permanent magnets 13. The lower end of the hollow sleeve 4 is made in the form of a cone with an annular sharp edge 14. At the upper end of the valve carriage 5 there are wedge-shaped scraper edges 15. The slider 10 of the spool mechanism 9 is provided with friction rings or plates 16.

According to the second option, the sucker rod pump for the production of highly viscous sand oil can be made with a plunger equipped with a rubber sleeve 17 (Fig.6), placed on the hollow sleeve 4. The rubber sleeve 17 has a protrusion 18 made along a helical line. The protrusion 18 interacts with the inner surface of the compression rings 8. At the same time, each compression ring 8 under a certain sector, rotated relative to each other, is pressed against the wall of the cylinder 1, thereby ensuring the tightness of the gap between the compression rings 8 and the inner wall of the cylinder 1.

According to the third embodiment, the sucker rod pump for the production of highly viscous sand oil can be performed with a plunger equipped with a compression unit (Fig. 7) containing a spiral compression spring 19 and O-rings 20. The compression spring 19 interacts with the inner wall of the cylinder 1 and the O-rings 20. The lower end of the compression spring 19 is fixed to the hollow sleeve 4 of the plunger, and the upper end is made with the possibility of axial movement. The amount of movement of the upper end of the compression spring 19 is controlled by the position of the valve carriage 5. The outer diameter of the compression spring 19 is made larger than the inner diameter of the cylinder 1. The spiral compression spring 19 can be made in the form of two or more compression springs interacting with the inner wall of the cylinder 1 and the sealing rings 20 .

The sucker rod pump operates as follows.

After the descent of the sucker rod pump into the well on the string of tubing and sucker rods 7, the reciprocating movement of the suckers 7 is carried out using a ground rocking machine. During the course of the string of pump rods 7 of the plunger 2 in the cylinder 1 “up” (FIG. 3), the pressure ball valve 6 closes the channel of the hollow sleeve 4. At the same time, the pusher 11 of the spool mechanism 9 presses the ball valve 6 against the seat (the seat in FIG. 1, 3, 5 not shown). The force of pressing the ball valve 6 with the pusher 11 to the seat is carried out by the friction force F _Tr between the slider 10 and the wall of the cylinder 1, directed in the opposite direction of movement of the rod string. During the stroke of the plunger 2 "up" in the subplunger cavity, a vacuum forms, as a result of which the suction ball valve 3 rises, and formation fluid (oil) is sucked into the subplunger cavity.

During the course of the column of sucker rods 7 and the plunger 2 "down" (figure 5), the suction ball valve 3 closes. Pressure is created in the subplunger cavity. Due to the friction force F _Tr between the slider 10 and the cylinder wall 1 pointing upward, the pusher 11 rises and releases the pressure ball valve 6 and the valve rises. As a result, oil flows from the subplunger cavity into the supraplunger cavity. Next, the pump cycle is repeated.

Thus, the proposed device allows to increase the reliability and durability of the sucker rod pump for the production of highly viscous sand oil. To increase its filling and supply coefficient by reducing the viscosity of oil and deposits of resins and paraffin in the valve operating area, eliminating oil leakage and sand entering the gaps between the plunger and the pump cylinder, as well as increasing the pump valves uptime.

Claims (3)

1. A sucker rod pump for producing highly viscous sand oil, comprising a cylinder with a suction ball valve, a plunger with a hollow sleeve and compression rings, a valve carriage with a pressure ball valve connected to a hollow sleeve and a rod string, characterized in that the plunger is equipped with a spool mechanism consisting of from a slider interacting with the inner wall of the cylinder and the pusher interacting with the ball of the discharge valve, a spring mounted on the hollow sleeve and interacting with the inner surface the radii of the compression rings, and the outer diameter of the spring is larger than the inner diameter of the compression rings by permanent magnets located on the lower ends of the cylinder and the plunger sleeve, and the lower end of the plunger sleeve is made in the form of a cone with an annular sharp edge, wedge-shaped scraper edges are made on the upper end of the valve carriage , the slider of the spool mechanism is provided with friction rings or plates. 2. A sucker rod pump for producing highly viscous sand oil, comprising a cylinder with a suction ball valve, a plunger with a hollow sleeve and compression rings, a valve carriage with a pressure ball valve connected to the hollow sleeve and a rod string, characterized in that the plunger is equipped with a rubber sleeve made with a protrusion along a helix interacting with the inner surface of the compression rings. 3. A sucker rod pump for the production of highly viscous sand oil, comprising a cylinder with a suction ball valve, a plunger with a hollow sleeve, a valve carriage with a pressure ball valve connected to the hollow sleeve and a rod string, characterized in that the plunger is equipped with a compression unit containing a spiral compression spring interacting with the inner wall of the cylinder and the o-rings, and the lower end of the spiral compression spring is fixed to the hollow sleeve of the plunger, and the upper end of which is made with possible axial displacement, and the outer diameter of the spiral compression spring is larger than the inner diameter of the cylinder sleeve, and the o-rings are installed between the hollow sleeve of the plunger and the spiral compression spring, while the spiral compression spring can be made in the form of two or more compression springs interacting with the inner wall cylinder and o-rings.

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