RU2300666C1 - Intake device for well pump - Google Patents

Abstract

FIELD: oil extractive industry, possible use during extraction of watered oil for decreasing speed of creation of high viscosity water-oil emulsion in lifting pipes column by organizing alternating feed of oil and water into intake of well pump.

SUBSTANCE: intake device of well pump contains sedimentation chamber connected to the sub of receiving section of well pump. In aforementioned chamber, U-shaped supplying branch pipe is partially located, its inlet end exiting the sedimentation chamber. Below sedimentation chamber a barrel with apertures in upper part is located, aforementioned barrel being connected to sedimentation chamber by inlet channel made in form of a pipe. An additional chamber is located between chamber and barrel and equipped with upper and lower lids. Inlet channel is composed of upper and lower branch pipes, plugged from top and bottom respectively, provided with respectively top and bottom side apertures. Upper branch pipe is rigidly connected to upper lid of additional chamber and is non-hermetically connected to well pump sub. Lower branch pipe is rigidly connected to lower lid and barrel bottom. Additional chamber is connected by means of upper and lower branch pipes through upper and lower side apertures respectively to internal spaces of sedimentation chamber and barrel. Inlet end of U-shaped supply branch pipe is made in form of side apertures in sedimentation chamber, positioned on the same level with upper side apertures of upper branch pipe. U-shaped supply branch pipe is formed by a pipe which is hermetically inserted between upper lid of additional chamber and the sub in intake section of well pump, and which is located between sedimentation chamber and upper branch pipe and is made with side apertures locate above the side apertures of sedimentation chamber.

EFFECT: lower costs and laboriousness of device manufacture, increased maintainability, increased reliability of device operation in wells with highly viscous oil.

1 dwg

Description

The invention relates to the oil industry and can be used in the production of flooded oil to reduce the rate of formation of a highly viscous water-oil emulsion in a column of elevator pipes by organizing the alternate supply of oil and water to receive a well pump.

The well-known "Entrance device of a borehole pump" (RF patent No. 2213269, class F04D 13/10, publ. Bull. No. 27 of 09/27/2003), including a U-shaped inlet pipe, sub of the receiving part of the borehole pump, settling chamber, having an inlet channel in the lower part, and an additional settling chamber located on the U-shaped inlet pipe at the point of changing the direction of fluid flow, and the channel sections of the U-shaped inlet pipe are made circular and formed by pipes eccentrically placed one into the other.

The disadvantages of the device are the high complexity and cost of its manufacture, since when welding the caps to the outer pipe, it is necessary to ensure their sufficiently high alignment, which can be achieved only by using special devices, high metal consumption of the device, since all parts and assemblies used are made of metal, low maintainability, the inability to assess the condition of the pipes inside the device.

The "Borehole pump inlet device" is known (RF patent No. 2232294, class F04B 47/00, publ. Bull. No. 19 of July 10, 2004) containing a settling chamber connected to the sub of the receiving part of the well pump, in which U -shaped inlet pipe, one end of which is led out to the settling chamber, and the settling chamber has an inlet channel in the lower part with a section smaller than the passage section of the settling chamber. The input device is additionally equipped with a glass made with holes in the upper part and connected to the settling chamber by an inlet channel made in the form of a tube placed in the glass, the lower end of which is located below the glass openings, and the upper end is located in the settling chamber at some distance from its bottom .

The disadvantages of the device are the high complexity of its manufacture, high metal consumption, as well as low reliability when operating waterlogged wells with highly viscous oil, during pumping of which hydraulic losses increase in the channels of the U-shaped inlet pipe, and the pressure of the height of the water column in the inlet channel becomes insufficient to compensate increased hydraulic losses.

The objective of the invention is to reduce the cost and complexity of manufacturing the device due to the exclusion of welded operations during its assembly and devices that ensure the alignment of the welded elements, to reduce the metal and cost of the device due to the use in its manufacture of cheaper non-metallic pipes, as well as to increase reliability devices in wells with high viscosity oil.

The problem is solved by an input device containing a settling chamber connected to the receiver of the receiving part of the well pump, in which a U-shaped supply pipe is partially placed, the inlet end of which is led out to the settling chamber, a glass located below the settling chamber with holes in the upper part, which is connected to the settling chamber camera input channel made in the form of a tube.

What is new is that between the settling chamber and the cup there is an additional chamber equipped with upper and lower covers, and the inlet channel is made up of a composite of upper and lower pipes, muffled respectively from above and below, equipped with upper and lower side holes, respectively, the upper pipe being rigidly connected with the top cover of the additional chamber and leaky with the sub of the borehole pump, and the lower pipe is rigidly connected to the bottom cover and to the bottom of the glass, while the additional camera is communicated using the upper and lower nozzles through the upper and lower side openings, respectively, with the internal spaces of the settling chamber and the cup, and the input end of the U-shaped inlet pipe is made in the form of side holes in the settling chamber, located at the same level with the upper side holes of the upper nozzle, and the U-shaped inlet pipe is formed by a hermetically inserted between the upper cover of the additional chamber and the sub of the receiving part of the borehole pump, placed between settling chamber and the upper pipe and made with side holes located below the side holes of the settling chamber.

The drawing schematically shows a General view of the device.

The input device comprises a settling chamber 2 connected to the receiving part 1 of the downhole pump. Below the settling chamber 2, there is a glass 3 with holes 4 in its upper part, which is connected to the settling chamber 2 by an input channel 5 made in the form of a tube.

Between the settling chamber 2 and the glass 3 there is an additional chamber 6 equipped with upper 7 and lower 8 covers, and the inlet channel 5 is made up of a composite of the upper 9 and lower 10 nozzles, muffled respectively from above and below, equipped with upper 11 and lower 12 side openings, respectively. The upper pipe 9 is rigidly connected to the upper cover 7 of the additional chamber 6 and is leaky with the sub 1 of the receiving part of the downhole pump. The lower pipe 10 is rigidly connected to the lower cover 8 and to the bottom 13 of the glass 3. The additional chamber 6 is communicated by means of the upper 9 and lower 10 pipes through the upper 11 and lower 12 side holes, respectively, with the inner space 14 of the settling chamber 2 and the inner space 15 of the glass 3 .

The input end of the U-shaped inlet pipe is made in the form of side holes 16 in the settling chamber 2, located at the same level with the upper side holes 11 of the upper pipe 9, a U-shaped inlet pipe is formed hermetically inserted between the upper cover 7 of the additional chamber 6 and the sub 1 the receiving part of the downhole pump with a pipe 17 located between the settling chamber 2 and the upper pipe 9 and made with side holes 18 located below the side holes 16 of the settling chamber 2.

This embodiment of the device eliminates weld operations during the assembly of the device and makes it possible to use cheaper non-metallic pipes as a cup 3, a settling chamber 2 and a pipe 17, for example, from an assortment of commercially available polyethylene pipes.

The assembly of the elements that make up the settling chamber 2 can be performed as follows. The upper pipe 9, made with a stop 19, is inserted into the hole 20 of the top cover 7 until it fits on the stop 19. Then, the end of the pipe 17 is inserted into the cylindrical groove 21 made on the top cover 7 and corresponding to the inner diameter of the pipe 17, while the side holes 18 should be located on the side of the top cover 7. In another cylindrical groove 21, made on the top cover 7 and corresponding to the inner diameter of the settling chamber 2, the settling chamber 2 is inserted, while the side holes 16 made in the settling chamber Leray 2 must be placed opposite the top cover 7 side. Then, on the opposite side from the top cover 7, a sub 1 of the downhole pump receiving section is mounted on the other end of the upper pipe 9 so that the ends of the pipe 17 and the settling chamber 2 fit into the cylindrical grooves 21 corresponding to their diameters made on the sub 1 of the downhole pump receiving section. In this position, the upper cover 7 and the sub 1 of the receiving part of the downhole pump are fixed with a plug 22 on the upper pipe 9.

The assembly of the elements that make up the glass 3 is made in a similar way. The lower pipe 10, also made with a stop 19, is inserted into the hole 20 of the lower cover 8 until it fits on the stop 19, while the lower side holes 12 should be located closer to the end of the lower pipe 10 opposite from the lower cover 8. Then, into the cylindrical groove 21, made on the bottom cover 8 and corresponding to the inner diameter of the glass 3, the end of the glass 3 is inserted, while the holes 4 should be located on the side of the lower cover 8. On the opposite side of the lower cover 8, a bottom is placed on the end of the lower pipe 10 13 so that the opposite end of the cup 3 enters the cylindrical groove 21 made on the bottom 13. In this position, the lower cover 8 and the bottom 13 are fixed with a plug 22 on the lower pipe 10. Then between the upper 7 and lower 8 covers is located and connected to them additional camera 6.

The device operates as follows.

The device is installed in the well directly below the well pump (not shown). The pump is put into operation. The reservoir fluid entering the well under the influence of gravitational forces is separated in the well into oil and water (not shown). In the steady state of operation of the pumping unit, the water-oil interface (hereinafter - VNR) is within the height of the device and moves between the side holes 16 of the settling chamber 2 and the holes 4 of the cup 3, since the device switches to the selection of either water or oil due to the imbalance of the columns fluid in the channels of the device.

Oil enters the device through the side openings 16 in the settling chamber 2, then moves down the cavity 23, reaches the side openings 18 in the pipe 17, through which it enters the internal space 14. Then through the internal groove 24 and the windows 25, made in sub 1 the receiving part of the borehole pump and providing leaks in the connection of the upper pipe 9 to the sub 1 of the receiving part of the borehole pump, oil enters the pump (not shown). When oil flows from the cavity 23 into the inner space 14, the direction of oil movement is reversed, which contributes to the separation of mechanical impurities and their subsidence on the surface of the top cover 7. The distance between the side holes 18 and the top cover 7 determines the volume of the part of the settling chamber 2, where during operation accumulation of solids is possible.

As oil is taken from the well, the BHP boundary rises, reaches the lateral openings 16 of the settling chamber 2. The equilibrium of the oil columns in the U-shaped supply pipe and the water in the input channel 5 is violated and the device switches to water selection.

The selection of water is carried out through the holes 4 of the glass 3. On the inner space of the 15 glass 3, the water moves down. Then, through the lower side openings 12, water enters the lower pipe 10 of the inlet channel 5 and, moving upward, enters the additional chamber 6. Next, the water moves along the upper pipe 9 and leaves it through the upper side holes 11. Then through the inner groove 24 and the windows 25, in sub 1 of the receiving part of the downhole pump, water enters the pump (not shown). The placement of the lower side holes 12 below the holes 4 allows you to change the opposite direction of the flow of water in the glass 3, which contributes to the separation of possible mechanical impurities and their subsidence on the bottom 13.

As water is taken from the well, the BHP boundary in the borehole decreases, it also decreases in the cavity 23 connected to the borehole through the lateral holes 16. And if, when pumping low-viscosity oil, the device switches to oil selection when the BHP border reaches the lower part of the U-shaped supply pipe ( in this case, there are no lateral holes 18 in the pipe 17), then in a well with high viscosity oil, switching to oil extraction does not occur at this location of the BHP boundary, since significant hydrodynamic collisions arise when the oil moves water, which prevents its flow through the cavity 23 and the inner space 14, forming a U-shaped inlet pipe, while water will continue to flow through the inlet channel 5 to the pump. The higher the viscosity of the oil, the lower the BHP boundary in the well falls and without the use of an additional chamber 6 extending the input channel 5, the BHP boundary can drop to the holes 4 of the cup 3. In this case, both oil and water will enter the device through the holes 4, the BHP border in the well will be installed at the level of these holes, and the device will not work.

In order to increase the reliability of the input device in wells with highly viscous oil, an additional chamber 6 is used in the device, which allows reducing the BHP boundary by the necessary distance from the lower part of the U-shaped supply pipe. In this case, the pressure loss during the movement of highly viscous oil in the U-shaped supply pipe will be compensated by the increasing pressure of the water column in the inlet channel 5, the length of which is increased by the additional chamber 6, and the device switches to oil selection.

Further cycles are repeated.

The location of the upper side holes 11 in the upper pipe 9 of the input channel 5 at the same level with the side holes 16 in the settling chamber 2 provides equal and maximum possible heights of the cavity 23 and the inner space 14 of the U-shaped inlet pipe, since the higher the height of the U-shaped inlet pipe , the larger portions of oil and water will be supplied to the pump, ceteris paribus, and the higher their mixing from the pump.

The use of the device allows to reduce the cost and complexity of manufacturing the device due to the exclusion of welded operations during the assembly of the device and devices ensuring the alignment of the welded elements, to reduce the metal consumption and the cost of the device due to the use of cheaper non-metal pipes in its manufacture, for example, from a range of commercially available polyethylene pipes, which can be installed between the covers of the device, to increase maintainability due to the simplicity of assembly-disassembly OPERATION AND possible replacement of worn any of its elements, as well as increase the reliability of the device operation in the high-viscosity oil wells due to the use of the additional chamber arranged between the settling chamber and the cup.

Claims (1)

A borehole pump inlet device comprising a settling chamber connected to the receiver receiving section of the borehole pump, in which a U-shaped supply pipe is partially placed, the inlet end of which is led out to the settling chamber, a glass located below the settling chamber with holes in the upper part, which is connected to the settling chamber an input channel made in the form of a tube, characterized in that between the settling chamber and the glass there is an additional camera equipped with upper and lower covers, and the input channel made of a composite of upper and lower nozzles, muffled respectively from above and below, provided with upper and lower side holes, respectively, the upper nozzle being rigidly connected to the upper cover of the additional chamber and leaking to the sub of the well pump, and the lower nozzle being rigidly connected to the lower cover and bottom glass, while the additional camera communicates using the upper and lower nozzles through the upper and lower side holes, respectively, with the inner spaces of the sludge a chamber and a cup, the inlet end of the U-shaped inlet pipe made in the form of side holes in the settling chamber located at the same level with the upper side holes of the upper pipe, and the U-shaped inlet pipe is formed tightly inserted between the upper cover of the additional chamber and the receiver sub part of the downhole pump with a pipe placed between the settling chamber and the upper pipe and made with side openings located below the side openings of the settling chamber.