RU2273767C1 - Differential sucker-rod pump - Google Patents

Abstract

FIELD: oil producing industry.

SUBSTANCE: invention relates to differential sucker-rod pumps and it can be used for pumping out high-viscosity liquids. Proposed differential sucker rod pump has cylinder coupled with tubing string which accommodates differential plunger coupled with sucker-rod string. Upper step of larger diameter plunger with mechanical seal has through channel, being equipped with delivery valve, and lower step of smaller diameter plunger is made in form of solid rod. Ring space enclosed between walls of cylinder and surface of rod forms working chamber of pump with suction valve made in form of plate with hole coaxial with cylinder through which solid rod is passed, being provided with mechanical seal. Intake filter in form of perforated cylindrical tube is installed lower than suction valve. Solid rod passes inside intake filter along its axis, and on its lower part piston is installed mechanically sealed relative to inner wall of intake filter. Perforation of cylindrical tube is made in form of conical holes or longitudinal slots widening in direction from axis of filter.

EFFECT: improved reliability and efficiency of operation of differential sucker-rod pumps.

2 cl, 1 dwg

Description

The invention relates to techniques for oil production, in particular to differential sucker rod pumps, and can be used for pumping highly viscous fluids from wells.

A well-known sucker-rod pumping unit for producing highly viscous oil, comprising a ground drive suspended in a well cavity on a tubing string with a suction and discharge valves, in the cylinder of which a hollow plunger connected to the guiding string of the sucker rods is connected, connected with a guide pulley and a load mounted under the plunger; the annular space of the well is equipped with stabilizing shoes installed along the entire length of the tubing, outside of which there is a string of pump rods made flexible and centered relative to the annular space with stabilizing shoes, the upper end of which is fixed to the ground drive, and the lower end is on the outer surface of the pump compressor pipes (see patent RU 2059884, class F 04 B 47/00, 05/10/1996).

The disadvantages of the known solutions are the relatively low efficiency and reliability of the downhole pumping unit.

The closest to the invention in terms of technical essence and the achieved result is a differential sucker rod pump comprising a housing made in the form of a cylinder in which a differential plunger connected to a string of sucker rods is installed, the upper stage of the larger diameter plunger having a through the channel is equipped with a discharge valve, and the lower stage of the smaller diameter plunger is made in the form of a monolithic rod, while the annular space enclosed between the by the cylinders of the cylinder and the surface of the plunger, it forms a working chamber of the pump with a suction valve made in the form of a plate coaxial with the cylinder with a hole through which a monolithic rod is hermetically passed (see utility model patent RU No. 39366, class F 04 В 47/00, 07/27/2004).

This differential sucker rod pump showed good results in the production of highly viscous oil, as well as oil with a high content of sand, mechanical impurities, paraffin and resinous substances. However, to clean the inlet filter, in case of clogging, it is necessary to flush by supplying fluid through the tubing. To do this, it is necessary to stop the pump, raise the rod string using a hoist to a certain height so that the piston leaves the cylinder, and the rod leaves its seal (5-7 meters), and pump clean fluid through the pump and filter. This time-consuming operation requires a shutdown of the pump, which leads to the loss of oil production.

The problem to which the present invention is directed, is to increase the reliability and efficiency of differential sucker rod pumps.

This problem is solved due to the fact that the differential sucker rod pump contains a cylinder connected to the column of pump tubes, in which a differential plunger connected to the column of pump rods is installed, the upper stage of the larger diameter plunger with mechanical seal has a through channel and is equipped with a discharge valve, and the lower stage the smaller diameter plunger is made in the form of a monolithic rod, while the annular space enclosed between the cylinder walls and the rod surface forms a working space a measure of the pump with a suction valve, made in the form of a plate coaxial with the cylinder with an opening through which a monolithic rod is passed hermetically by means of a mechanical seal, while a suction filter in the form of a perforated cylindrical pipe is installed below the suction valve, a monolithic rod passes into the suction filter along its axis and on its lower part there is a piston with a mechanical seal relative to the inner wall of the intake filter, and the perforation of the cylindrical pipe is made in the form of conical holes holes or longitudinal slots expanding in the direction from the axis of the filter.

The perforated cylindrical pipe forming the intake filter has an inner diameter larger than the diameter of the upper stage of the pump plunger.

In the course of the study of the operation of the differential sucker rod pump, it was revealed that during its operation a guaranteed movement of the rod string down due to the additional hydraulic load on the upper stage of the plunger and the rod is ensured, the rods do not experience alternating loads, which increases their performance and durability, and the travel losses of the upper one are significantly reduced steps of the plunger by reducing deformations of the rod string (they do not twist into a spiral). However, the viscosity and contamination of the liquid medium pumped out of the well have a particularly great influence on the conditions of absorption. Due to the high viscosity of the formation fluid, hydraulic losses in the filter and in the suction valve significantly increase, which leads to the release of gas from the fluid, a decrease in the pump flow rate and the occurrence of shock during operation. The filters gradually become clogged, which leads to a complete stop of the pump. In order for the filter to work for a sufficiently long time, a large number of holes are drilled, the total passage section of which is tens and hundreds of times larger than the required passage section of the hole in the seat of the receiving valve. Washing the filters does not always lead to the desired result. You have to use different types of self-cleaning filters, such as mesh and slotted. However, they are not reliable and have a high cost.

Fastening the receiving filter to the pump in the form of a perforated cylindrical pipe, placing a monolithic rod inside the receiving filter along its axis and installing a piston with a mechanical seal on the monolithic rod relative to the inner wall of the receiving filter, as well as perforating the cylindrical pipe in the form of conical holes or longitudinal slots, expanding in the direction from the axis of the filter, allows you to solve the problem. In this case, the differential plunger and piston are performed using mechanical seals according to the patent of the Russian Federation No. 2037077.

Depending on the conditions in the well (gas content in the fluid, fluid viscosity, etc.), the perforated cylindrical pipe forming the intake filter is made with an inner diameter larger than the inner diameter of the upper stage of the pump plunger. Thus, the internal cavity of the filter has a larger volume than the working volume of the pump. When the pump is operating, a piston located on a monolithic rod, with its mechanical seal, removes mechanical impurities that are stuck and stuck in the perforation holes and clog the filter, and when the piston moves towards the suction valve, mechanical impurities are displaced from the filter into the annulus of the well by a fluid stream abundant in a perforated pipe. Of great importance for organizing self-cleaning of the intake filter is the ratio of the dimensions of the intake filter and the diameter of the upper stage of the plunger. Excess fluid in the intake filter is used to flush it with each stroke of the piston on a monolithic rod towards the suction valve. In addition, due to excess fluid, the filling factor of the pump cylinder increases. With a suction stroke in such a pump, pressure losses in the valve are significantly reduced and, therefore, no gas is released from the liquid. The filter also acts as a booster pump.

The drawing shows a longitudinal section of a differential sucker rod pump.

The differential sucker rod pump contains a cylinder 1 connected to the column of pump tubes, in which a differential plunger 3 connected to the column of pump rods 2 is installed, the upper stage 4 of the larger diameter plunger 3 with a mechanical seal 5 has a through channel 6 and is equipped with a discharge valve 7, and the lower stage the plunger 3 of smaller diameter is made in the form of a monolithic rod 8, while the annular space 9, enclosed between the walls of the cylinder 1 and the surface of the rod 8, forms a working chamber of the pump with a suction cell Apan 10, made in the form of a plate 11, coaxial with cylinder 1, with an opening 12, through which a monolithic rod 8 is passed hermetically using a mechanical seal 13. A suction filter 14 is installed in the form of a perforated cylindrical pipe below the suction valve 10. A monolithic rod 8 extends into the intake filter 14 along its axis and a piston 15 is installed on its lower part with a mechanical seal 16 relative to the inner wall of the intake filter 14, and the perforation of the cylindrical pipe is made in the form of conical holes 17 or longitudinal slots expanding in the direction from the filter axis .

The perforated cylindrical tube forming the intake filter 14 has an inner diameter of preferably 10-50% or more than the diameter of the upper stage 4 of the pump plunger.

Differential sucker rod pump operates as follows.

When the differential plunger 3 moves down, the discharge valve 7 opens and passes liquid from the working chamber to the through channel 6 and then to the tubing.

At the same time, the rod 8 moves down the piston 15 with a mechanical seal 16 mounted on its lower end. In this case, the rings of the mechanical seal 16 clean off from the inside of the perforated pipe of the intake filter 14 all particles adhering and stuck in the holes 17 and clean the filter. The particles settle down and collect in the hopper 18 or are displaced together with the liquid from the intake filter 14 out into the annulus.

At the same time, through the holes 17 cleared of dirt, which turned out to be above the piston 15, liquid from the annulus enters the internal cavity of the intake filter 14. The hydraulic resistance when liquid enters through the holes in the intake filter 14 is overcome by a column of liquid in the annulus (backwater) and does not affects the pump suction process. At the end of the down stroke, the pressure inside and outside the intake filter 14 is equalized. No gas is released. On the contrary, before the suction stroke, the liquid by inertia will tend to enter the intake filter 14, that is, create additional backwater.

When the piston 15 along with the differential plunger 3 upward, the discharge valve 7 closes and the suction valve 10 opens. The suction process begins. Compared to conventional pumps, filling the working chamber of this pump is more efficient due to the following reasons:

- friction forces in the mechanical seal 13 facilitate the lifting of the plate 11 of the valve 10 and reduce hydraulic losses in the valve;

- due to the fact that the cross-sectional area of the working chamber of the pump is less than the cross-sectional area of the intake filter 14, the piston 15 will push the liquid out of the intake filter 14 partially into the working chamber of the pump and partially out into the annulus. The resistance in the suction valve 10 is overcome not due to the liquid column in the annulus, but due to the back pressure created by the upward movement of the piston 15, which is driven by the top drive. In this case, the working chamber of the pump is better filled with liquid and at the same time the filter is cleaned, mechanically and hydraulically.

The piston 15 may be optionally equipped with a brush for better cleaning of holes from dirt.

The result is:

1) reliable operation of the pump on viscous and contaminated liquids due to forced and continuous cleaning of the filter;

2) improving the filling conditions of the working chamber of the pump. Pump operation is possible in wells with a high gas content in oil. Pumps can operate with low back pressure (deepening under a dynamic level), and, therefore, expensive tubing pipes are saved. Due to depression, the flow rate of wells, etc. can be increased.

Depending on the operating conditions (gas, sand, solids, viscosity, etc.) for each pump size, the appropriate diameters of the perforated pipes can be selected in order to ensure the most efficient oil pumping mode.

The present invention can be used in the oil and other industries where it is necessary to pump various fluids from the well, including highly viscous oil.

Claims (2)

1. A differential sucker rod pump comprising a cylinder connected to a column of pumping tubes, in which a differential plunger connected to a string of pumping rods is installed, the upper stage of the larger diameter plunger with a mechanical seal having a through channel and equipped with a discharge valve, and the lower stage of the smaller diameter plunger in the form of a monolithic rod, while the annular space enclosed between the cylinder walls and the rod surface forms the working chamber of the pump with a suction valve, filled in the form of a plate coaxial with the cylinder with an opening through which a monolithic rod is passed hermetically by means of a mechanical seal, characterized in that a receiving filter in the form of a perforated cylindrical pipe is installed below the suction valve, the monolithic rod passes into the receiving filter along its axis and on its lower of the part there is a piston with a mechanical seal relative to the inner wall of the intake filter, and the perforation of the cylindrical pipe is made in the form of conical holes or longitudinal slots , Expanding in the direction of the filter axis. 2. The differential sucker rod pump according to claim 1, characterized in that the perforated cylindrical pipe forming the receiving filter has an inner diameter larger than the diameter of the upper stage of the pump plunger.