SU1000603A1 - Well pumping unit - Google Patents

Description

(54) BOTTOM PUMP INSTALLATION

one

The invention relates to a technique for the extraction of oil, in particular to well pumping installations for lifting saline, paraffinic and corrosive fluids, and can be used in the oil industry.

A well-known downhole pumping unit for lifting saline and paraffin fluids, comprising a submersible pump connected to the column of pumping tubes with an electric motor installed beneath and a chemical reagent dispenser in the form of a container connected to the annulus of the well 1.

A disadvantage of the known borehole pumping unit is the low dosing accuracy depending on the pressure loss of formation fluid in the annulus, which reduces the economics of the installation.

The purpose of the invention is to increase its efficiency by improving the accuracy of dosing B depending on the pressure drop in the annulus.

This goal is achieved by the fact that the tank is equipped with an elastic medium separator installed with the formation of two chambers, one of which is connected to the discharge cavity of the pump, and the other is filled with reagent and connected to the annular space, and the tank is installed under the electric motor.

5 FIG. 1 shows the upper part

well pumping unit, general view, section; in fig. 2 - bottom part of the borehole pumping unit, general view, section; in fig. 3 - screw type choke on

ten

The well pump installation contains a submersible pump 2 connected to the column of pump tubes 1 with an electric motor 3 installed under it and a liquid chemical agent dispenser 4, made in

15 as a reservoir 5 connected to the annulus 6 of the well. The container 5 is equipped with an elastic deaerator 7 installed to form two chambers 8 and 9, one of which is designed to collect 2Q of the formation fluid and communicates with the discharge cavity 10 of the pump 2 through tube 11, and the other 9 is filled with reagent and communicated with annulus 6 through tube 12, with the capacitance 5 mounted above the electric motor 3.

The dispenser 5 includes an upper section 13 and sections 14, similar in construction to the lower part of the upper section.

The upper section 13 has a compensator 15, which communicates with the cavity 16, inside which there is a screw-type choke 17 connected to the gear multiplier 18, and through the rack 19 interacts with the diaphragm actuator 20. In addition, a filter 21 is installed in the upper part of section 13, communicating with inlet channel 22 via pipe 11 with the discharge cavity 10 of pump 2 and output channel 23 with a reducing hydraulic valve 24 providing for lowering the pressure of formation fluid supplied by pump 2 and maintaining a constant pressure The pressure differential in the chamber 9 and the well is at the level of the outlet openings 25 of the outlet channel of the throttle 17.

For better mixing of the chemical reagent with the formation fluid, a turbulizer 26 is installed on the body (not indicated) of the upper section 13.

A liquid valve 27 serves to fill the liquid chemical into chamber 9, and a stopper 28 serves to discharge air from it. But air is released from chamber 8 through a stopper 29.

Section 14 is provided with a flange plug 30 in which a burst-type discharge plate valve 31 is mounted, designed to drain the formation fluid from chamber 8 before lifting the metering device from the well.

The screw throttle 17 (Fig. 3) consists of a housing 32, a slider 33 with a screw capillary groove 34 cut on it, driven by screwing or unscrewing the screw 35, and communicating through tube 12 with camera 9 and through tube 36 through chamber 37 and outlets 25 - with a well.

The diaphragm actuator 20 is provided with a membrane 38 and is connected by a tube 39 to the annulus 6 of the well.

A well pump installation operates as follows.

When the motor 3 is turned on, the reservoir fluid under pressure developed by the submersible pump 2 flows through pipework 11 through filter 2 to the reducing hydraulic valve 24 and chamber 8.

The pressure in the chamber 8 is transmitted through the flexible separator 7 into the chamber 9, in which there is a liquid chemical reagent. Under the action of this pressure, the liquid chemical reagent through the tube 12, the droop .ib 17, the tube 36 and the extraction holes 25 enters the annulus 6 of the well.

When changing the selection of formation fluid from the well, the pressure drop in the annular space 6 of the well between points a and b is changed, which through the compensator 15 and the tube 39 is transferred to the membrane 38. Under the action of the changed non-pressure pressure the membrane 38 moves gear rail 19 and gear 1; 1 screw 18 onto screw 35. when screwing or unscrewing 1P1 and screw 35 into slider 33, the last peg. l 17. The change in the hydrodynamics of the throttles 17 leads to a change in the flow rate of the rec- chgg.

Claims (1)

Invention Formula Well pumping station for mineralized and mineralized mineral water pumping systems: 1yuds, containing one of the submersible isacoc immersible pump’s .CXKJH pumping pipes with electric motor installed under it, and the liquid dispenser of hn.michesky () 1H) reagent, filled. in the form of capacity. with annular borehole space, characterized in that, in order to increase its cost efficiency by increasing the dosing accuracy depending on the flow pressure of the formation fluid in the annular space, the tank is equipped with an elastic medium separator, installed 1m to form two chambers one of which communicates with the injection cavity of the pump, and the other is filled with reagent and is connected with the annulus, with the capacitance of the pumps under the electric motor. Sources of information taken into account for exertize 1. Copyright certificate СХСР № 819398, cl. F 04 B 47/02, 1979.  . J7 J7 I fig 2 FIG. five