RU2821685C1 - Downhole sucker-rod pump of double action - Google Patents

Abstract

FIELD: pumps.

SUBSTANCE: invention relates to pumping equipment and can be used in oil production industry as part of downhole pumping equipment. Downhole sucker-rod pump of double action includes a sub, upper and lower pressure valves with seats, a hollow plunger arranged in a cylinder with possibility of back-and-forth movement. Below the cylinder there is an additional cylinder with a mandrel and a hollow plunger connected to the cylinder by means of couplings and a branch pipe with inlet channels or a filter. Lower end of the additional cylinder is blind. Hollow plungers are installed on mandrels with possibility of longitudinal mobility relative to mandrels, limited at its one end by a stop, and at the opposite end by a wear-resistant seat. Mandrel of upper pressure valve is installed so that wear-resistant seat is arranged in its lower part. Mandrel of lower pressure valve in additional cylinder is installed so that wear-resistant seat is located in its upper part, and is rigidly connected to mandrel of lower pressure valve by rod, length of which is equal to length of pump stroke. Mandrel of the upper pressure valve is rigidly connected to the pump rod, the length of which is equal to the sum of the lengths of the pump stroke and the pump rod seal housing. Above the pump rod seal housing there is a sub with the inlet of the bypass channel connecting the lower end of the additional cylinder with the cavity of the pump string. Lower end of the bypass channel is equipped with a ball valve. Pressure valves are used for forced actuation.

EFFECT: invention is aimed at creation of relatively simple, reliable pump with high efficiency and improvement of energy efficiency of downhole pumping equipment.

2 cl, 4 dwg

Description

The invention relates to the field of pumping technology and can be used in the oil industry as part of downhole pumping equipment.

A double-acting deep-well sucker rod pump is known containing a cylinder released on tubing pipes. Inside the pump cylinder, a piston moves. The piston rod is attached to the bottom of the sucker rods and passes through the packing. Each end plane of the piston actuates two valves. In total, the pump has two suction and two discharge valves. Through the lower discharge valve, the liquid enters the pump and compressor pipes through a bypass channel in the walls of the pump cylinder (N.D. Dragotescu, “Deep Pumping Oil Production,” M., Nedra, 1966, p. 264).

Disadvantages include the relative difficulty of placing valves in a limited diametrical space and the fragility of the deep stuffing box seal.

A “double-acting pumping system” is known, containing a casing string with two exposed layers, a pump running on a pipe string, located in the casing string with the formation of an annular space between them, which is separated by a packer located between the exposed layers, and the pump, above and below which, above The packer contains the upper and lower inlet openings with valves and is equipped with a piston configured for reciprocating movement, while the pump outlet from above, through a pipe string, communicates through the upper outlet valve with the space under the packer. This design of the installation allows a significant part of the produced water to be pumped into the underlying reservoir opened by the well without lifting it to the surface, thereby reducing the cost of oil production (US patent No. 5497832, IPC E21 B43/38, 43/40 dated 03/12/1966).

The disadvantages of such a system are the complexity of installation, including due to the presence in the design of a packer, which is necessary in this pumping system for pumping produced water into the underlying formation, without lifting it to the surface.

A double-action sucker rod pump is also known, containing a cylinder having a lower suction valve and connected to the pipe string using a sub equipped with upper suction and discharge valves, and a hollow plunger placed in the cylinder to form sub-plunger and supra-plunger cavities and the possibility of reciprocating movement , connected to a hollow rod and having a lower discharge valve, according to the invention the cylinder is made in stages with a lower stage of a larger diameter and an upper stage of a smaller diameter, in the side wall of the plunger above the lower discharge valve there is a through hole for communication between the cavity of the plunger and the chamber formed when it moves downwards in the lower stage of the cylinder, the upper stage of the cylinder is made with an internal diameter smaller than the internal diameter of the pipe string, the sub is made with an internal diameter smaller than the internal diameter of the pipe string, but not smaller than the internal diameter of the upper stage of the cylinder, the upper discharge valve is made in the form of a sleeve located on rod with the possibility of longitudinal movement along it upwards with excess pressure in the above-plunger cavity of the cylinder and movement downwards in the liquid under its own weight, and is equipped with a seat formed at the upper inner end of the sub, and between the plunger and the upper discharge valve on the rod there is a stop made with the possibility interaction with the upper discharge valve (patent RU No. 2436996, F04B 47/00, publ. 12/20/2011, bulletin. No. 35).

The disadvantages of the known pump are:

- complexity of installation;

- insufficiently large flow sections of the upper suction valve, which reduce the filling factor of the pump;

-low operational reliability of the upper discharge valve.

The technical objective of the present invention is to create a relatively simple, reliable pump with high efficiency and increase the energy efficiency of deep-well pumping equipment.

The technical result achieved by the invention is a reduction in hydraulic resistance of both the upper discharge valve and the lower discharge valve, the relative simplicity of the pump design and increased energy efficiency of deep-well pumping equipment.

The technical result is achieved by a double-acting downhole sucker rod pump containing a sub, upper and lower injection valves with seats, and a hollow plunger placed in a cylinder with the possibility of reciprocating movement.

What is new is that below the cylinder there is an additional cylinder with a mandrel and a hollow plunger, connected to the cylinder using couplings and a pipe with inlet channels or a filter, while the lower end of the additional cylinder is made blind, and the hollow plungers are mounted on mandrels with the possibility of longitudinal mobility along in relation to the mandrels, limited at one end by a stop, and on the opposite - by a wear-resistant seat, and the mandrel of the upper discharge valve is installed so that the wear-resistant seat is located in its lower part, and the mandrel of the lower discharge valve in the additional cylinder is installed so that the wear-resistant seat is placed in its upper part, and is rigidly connected to the mandrel of the lower discharge valve by a rod, the length of which is equal to the stroke length of the pump, and the mandrel of the upper discharge valve is rigidly connected to the pump rod, the length of which is equal to the sum of the stroke lengths of the pump and the pump rod seal housing, while above the housing In the pump rod seal, an adapter is placed with the inlet of a bypass channel connecting the lower end of the additional cylinder with the cavity of the pump pipe column, while the lower end of the bypass channel is equipped with a ball valve, while the discharge valves are forced-actuated.

Also new is that more than one hollow plungers with mandrels can be installed in each cylinder.

In fig. 1 shows a diagram of the proposed pump (upstroke), Fig. 2 shows a diagram of the proposed pump (downward stroke), Fig. 3. section A-A, version with a single bypass channel, in Fig. 4. section А-А, option with two bypass channels, where cylinder - 1, additional cylinder - 2, couplings - 3, pipe or filter - 4, mandrel - 5, 5', hollow plunger - 6, 6', longitudinal sampling - 7, stops - 8, 8', wear-resistant seat - 9, 9', wear-resistant sleeve - 10, 10', rod - 11, seal - 12, pump rod - 13, housing (pump rod 13) - 14, glass ( pump rod 13) - 15, seat (pump rod 13) - 16, bypass channel - 17, check valve - 18.

A double-acting downhole rod pump contains a sub, upper and lower discharge valves with seats, a hollow plunger 6 placed in cylinder 1 with the possibility of reciprocating movement.

Cylinder 1 (Fig. 1) is connected to an additional cylinder 2 using couplings 3 and a pipe 4 with inlet channels or a filter (instead of pipe 4).

In cylinder 1 there is a discharge valve, including a mandrel 5 on which a hollow plunger 6 is mounted.

Moreover, longitudinal selections 7 are made along the body of the mandrel 5.

In this case, at one end of the mandrel 5 there are stops 8, the outer diameter of which is larger than the inner diameter of the hollow plunger 6, and at the opposite end of the mandrel 5 a wear-resistant seat 9 is installed.

In this case, the lower end of the hollow plunger 6 is equipped with a wear-resistant sleeve 10, which, when moving upward, interacts hermetically with the wear-resistant seat 9.

In the additional cylinder 2, a similar injection valve is installed, only turned 180°, which, when moving upward, is forced to open, passing through the well fluid entering through the inlet channels of the branch pipe 4 or the filter into the cavity of the cylinder 2.

The mandrels 5 and 5' are rigidly connected to each other by a rod 11, the length of which corresponds to the stroke length of the pump. In the upper part of cylinder 1 there is a seal 12 of the pump rod 13, which includes a housing 14, a glass 15 and a seat 16. A bypass channel 17 through a check valve 18 connects the lower end of the additional cylinder 2 with the cavity of the pump pipe column (not shown in Fig. 1 -4).

The described pump operates as follows.

The pump is lowered into the well (not shown in Fig. 1-4) into the design interval on the pipe string (not shown in Fig. 1-4). After that, a string of rods with an automatic coupler is lowered (not shown in Fig. 1-4), after fixing the automatic coupler, they begin to cause an influx of well fluid.

When the string of rods with the pump rod 13 moves upward, the mandrel 5 of the upper discharge valve moves upward, and the hollow plunger 6, due to the friction of the outer surface of the hollow plunger 6 on the inner surface of the cylinder 1, moves down until the edge of the wear-resistant sleeve 10 stops in the wear-resistant seat 9, sealing this joint. In this case, the seal 12 of the pump rod 13 moves upward until it stops, opening the valve, a portion of the well fluid is supplied to the cavity of the pump pipes and to the wellhead (not shown in Fig. 1-4).

At the same time, in the cavity of the lower additional cylinder 2, a mandrel 5' the lower injection valve also moves upward, and the hollow plunger 6', due to braking on the inner surface of the additional cylinder 2, moves down until the hollow plunger 6' contacts the stop 8', the valve is forced to open and the well fluid fills the cavity of the additional cylinder 2.

When the string of rods with the pump rod 13 moves down, the seal 12 moves down until the glass 15 fits into the seat 16, the valve closes, the upper discharge mandrel 5 also moves down, the hollow plunger 6, due to the friction of the outer surface of the hollow plunger 6 on the inner surface of the cylinder 1 , moves upward relative to the mandrel 5, the injection valve opens, the well fluid fills the cavity of cylinder 1 through the inlet channels. At the same time, in the cavity of the lower additional cylinder 2, the mandrel of the lower injection valve 5' also moves down, the injection valve closes and the well fluid is squeezed out from the cavity of the cylinder 2, through the check valve 18 and the bypass channel 17, into the cavity of the pump pipes and to the wellhead.

Thus, the well fluid is supplied both during the upward and downward strokes.

Thanks to the use of the proposed valves, the problem associated with the release of gas from the well fluid is solved, hydraulic resistance is reduced and the efficiency of the pump increases, and in general the energy efficiency of downhole pumping equipment increases.

Claims (2)

1. A double-acting downhole sucker rod pump containing a cylinder connected to a string of pumping pipes, a sub, upper and lower discharge valves with seats, a hollow plunger placed in the cylinder with the possibility of reciprocating movement, characterized in that an additional cylinder with a mandrel and a hollow plunger connected to the cylinder using couplings and a pipe with inlet channels or a filter, wherein the lower end of the additional cylinder is made blind, and the hollow plungers are mounted on mandrels with the possibility of longitudinal mobility in relation to the mandrels, limited at one end by a stop, and on the opposite side - a wear-resistant seat, and the mandrel of the upper discharge valve is installed so that the wear-resistant seat is located in its lower part, and the mandrel of the lower discharge valve in the additional cylinder is installed so that the wear-resistant seat is placed in its upper part, and is rigidly connected to the mandrel of the lower discharge valve with a rod, the length of which is equal to the stroke length of the pump, and the mandrel of the upper discharge valve is rigidly connected to the pump rod, the length of which is equal to the sum of the stroke lengths of the pump and the pump rod seal housing, while above the pump rod seal housing there is a sub with the inlet of the bypass channel connecting the lower end of the additional cylinder with the cavity of the pumping pipe column, while the lower end of the bypass channel is equipped with a ball valve, and the discharge valves are forced-actuated. 2. The pump according to claim 1, characterized in that more than one hollow plungers with mandrels can be installed in each cylinder.