RU2114282C1 - Method and device for lifting gas-liquid mixture in wells - Google Patents

Abstract

FIELD: oil and gas production industry. SUBSTANCE: according to method, lifting of liquid by deep well pump is realized with utilization of gas energy and hydrostatic pressure of column of gas-liquid mixture which is located above pump intake. Liquid is delivered to deep well pump from top to bottom through annular space isolated from bottom hole with separation of gas. Gas is withdrawn and its lifting energy is spread over entire bore-hole of well. By utilizing pressure of degassed liquid column, part of load from mass of well product being lifted through column is removed. Device has deep well pumps, suction and delivery valves, strings of rods and pipes, and gas overflow valves. Lower pump is of single-action type with circular passage between body and housing and receiving chamber. Upper pump is made with double-action piston, side-located suction and delivery valves. Both pumps are connected to each other. Also provided is gas separator-demulsifier. Aforesaid arrangement of equipment allows for more full utilization of various kinds of potential energy contained in well product itself for enhancing efficiency in operating wells by deep-well sucker rod pumps. EFFECT: higher efficiency. 3 cl, 1 dwg

Description

 The invention relates to the oil industry, to the production of oil and gas.

 A known method of lifting liquid from wells with a sucker rod pump, including separating a deep-pumping unit freely released from a gas pump, consisting of a sucker rod pump comprising a housing, a plunger, suction and discharge valves, from a gas separator, tubing string, rod string wellhead stuffing box, rocking machine.

 The disadvantages of this method and the installation used are the inability to use the available potential energy for lifting the borehole product, expressed in various physical and structural properties of this product and the physical conditions of its lifting; very limited use of free gas energy for lifting a liquid, which is released from a liquid during a lift.

 The closest technical solution is a method of lifting liquid from wells using a rod deep-well pumping equipment consisting of a rod deep-well pump, a rod string, a tubing string with a gas transfer valve installed on the top of the pipe string.

 The disadvantages of this method and the used downhole pumping equipment are the inability to use for lifting the potential types of energy contained in the well production itself, the density difference of the various components of the produced fluid, enclosed in free gas released from the well fluid.

 The aim of the invention is a more complete use of various types of potential energy available in the borehole product itself to increase the efficiency of well operation with sucker rod pumps.

 The goal is achieved by the fact that in the method of lifting a gas-liquid mixture from wells with rod pumps using the lifting energy of the gas and the pressure of the hydrostatic column of the gas-liquid mixture located above the pump intake, the liquid is fed from top to bottom along the annular space isolated from the bottom of the well, having previously been separated from the annulus gas-liquid mixture, when turning the direction of the liquid from ascending to descending, gas, pump gas into the tubing and distribute the use of its lifting energy throughout the wellbore, and the pressure of the hydrostatic column of degassed liquid located above the pump intake, relieve part of the load from the weight of the well products being lifted along the pipe string.

 The goal is also achieved by the fact that the gas-liquid mixture supplied to the downhole pump is passed through demulsion filters and the surfactant is fed into it in a narrowed passage formed by the gas separator-demulsifier body and tubing.

 This goal is achieved by a unit having two pumps, an upper and a lower one, with the latter having a single action with an annular channel formed by its body and casing, and a receiving chamber, and the upper one is made with a double-acting piston, side suction and discharge gas transfer valves, the upper one the pump is designed for pumping gas, and the lower one is for pumping liquid, both pumps are interconnected by hollow rods and tubing and a gas separator-deem is installed under the gas pump lsator consisting of a container for the surfactant, with a filter housing arranged therein annular filters and passed through the filter tubes.

A comparative analysis of the proposed solution with the prototype shows that in the claimed method in order to more fully use the potential types of energy available in the borehole product itself, expressed in a different component composition having different physicochemical properties of the borehole product, the wellbore is divided into two intervals:
1. The interval of lifting the reduction of the oil reservoir by the combined use of reservoir energy in the form of a rational value of the bottomhole pressure, the lifting energy of the gas released from the oil during their movement through the annulus, using the hydrostatic pressure of the degassed liquid moving from a given upper point of this interval, back to the downstream of the pump located at a given depth in a downward flow along an annular space isolated from the bottom of the well.

 2. The interval of raising the production of the well by the combined use of energy transmitted by mechanical equipment and the re-lifting energy of the gas released from the fluid in the first interval of the well, by sucking it from the annulus and mixing with the fluid pumped out by the lower pump along the hollow rods, i.e. by reducing the density of this gas-liquid mixture by a predetermined amount.

 The proposed method is also different in that for a more complete use of potential types of energy when raising a borehole gas-liquid emulsion, the latter is subjected to preliminary preparation, which consists in supplying the Prevocel and other surfactants to a gas-liquid mixture, their movement in a narrowed section formed between the demulsifier body and production casing, in the separation of the evolved gas when the liquid stream is rotating from the ascending to the descending stream, in demulsification and in additional gas evolution during and liquid through the filters to destroy residual gas-liquid globule.

 The underground equipment differs from existing underground equipment in that the pumps are pumped separately from different depths by pumps of various designs: the liquid is a single-acting deep-well pump with a receiving chamber and an annular groove (ring space), through which the liquid enters the pump at a given high pressure , which allows not only to ensure full filling of the deep pump when the liquid is sucked in, but also to remove part of the load from the weight of the liquid and the rod string, gas is pumped out using a double pump actions, sucking in freely released gas from the annulus and pumping it into tubing, where it mixes with the liquid exiting the hollow rods, forming a gas-liquid mixture with a much lower density compared to the liquid, and therefore reduces the load on the weight of the liquid equipment.

 The above allows us to conclude that the claimed invention is interconnected by a single inventive concept.

 Comparison of the claimed technical solutions with the prototype made it possible to establish compliance with their criterion of "novelty."

 When studying other known solutions in the art, the features that distinguish the claimed invention from the prototype were not identified and therefore provide the claimed technical solution and significant differences.

 The invention is illustrated in the drawing, which presents a diagram of the proposed sucker rod pumping unit. The installation consists of two deep pumps 1 and 2: bottom 1 with a single-acting plunger pair 3 for pumping liquid; top 2 with a piston pair of double action 4 for pumping gas. The pumps are connected to each other by a column of tubing 6 and a column of hollow rods 5.

 Hollow rods with a hollow rod and a plunger of the lower pump, as well as with a hollow rod and a plunger of the upper pump, having flip openings 7 above the plunger, are connected using adapter couplings. In this case, the upper pump has a suction 8 and 9 and discharge valves 8 '' and 9 ''.

 Tubing 6 below the upper gas pump with a column of hollow rods and concentric outer tubes form an annular space 14, the upper part of which serves as a surface for a surfactant 13 and gas separator-demulsifier 15, in which are located below the receiving holes 10 ring filters 11 through which tubes for supplying surfactants from the upper pipe annular tank 13 to the narrowed passage formed between the gas separator and the casing (production) well string are passed.

 In the lower part, the tubing string through the branch pipe with holes is connected to the housing of the castle support and the outer pipes concentric to it 19, forming a receiving channel between them, communicating with the annular space 14.

 The method is as follows.

 The method consists in raising a gas-liquid mixture using potential types of energy contained in the products to raise the borehole products to the earth’s surface, released as the pressure of the medium decreases, while maintaining its temperature in rational ranges, light hydrocarbons in the gas state and the difference in hydrostatic pressures at various ratios of its constituent components. To do this, the gas-liquid mixture at the beginning of its bottom-hole zone of the well reaches a predetermined height in the annulus with the intensive release of dissolved gases from the liquid into the free state with the simultaneous upward movement of all components that make up the gas-liquid mixture, at which a rational rate of their rise is ensured by selection the cross-sectional area of the annulus, which also allows to reduce the specific loss of heat consumed when lifting per unit height, and therefore And provide the maximum possible reduction in density lifted mixture while maintaining the optimum value of bottom hole pressure.

 At the end of raising the gas-liquid mixture to a predetermined height, surfactants of the “Prevocel” and other brands are fed into it and the direction of its movement changes from ascending to descending, which is accompanied by intensive degassing of the liquid, which is then passed through an annular filter 11, gas separator-demulsifier 15 where they destroy the residual gas-liquid globules, which allows for a deeper phase separation of the well products into liquid and gas; the separated liquid flows down the annular space 14 to the intake of the pump 20, creating a pressure at its intake that completely dissolves the residual gas bubbles, creates a retaining force on the pump plunger, unloading the downhole pumping equipment from the part of the load created by the weight of the liquid being lifted, and ensures full filling the suction cavity of the deep pump with liquid.

 The separated gas from the liquid during the rotation of the jet in the filter 11 of the demulsifier accumulates in the upper part of the annulus of the well, from where it is sucked up by the upper double-acting pump 2, pumped into the tubing 6 and mixed with the liquid pumped by the lower liquid pump 1, lifted along the hollow rods 5, forming a gas-liquid mixture with a much lower density above this point.

 The installation works as follows: an emulsion gas-liquid mixture raised in the annulus with an established bottomhole pressure slightly higher than that installed at the bottomhole height of the device, before being pumped to the surface of the earth with a deep pump, it is subjected to preliminary preparation.

To do this, a surfactant "Prevocel" or others is dosed under the gas separator-demulsifier 15, which, then passing through the narrowed passage formed between this device and the production string, is mixed with the emulsion mixture. This contributes to the rotation of the fluid flow over the device in the opposite direction to the phase separation of the mixture into gas and liquid. The gas that is separated in this case is accumulated in the upper part of the annulus, and the liquid is guided through the annular space 14 to the intake of the lower liquid deep pump, which is then pumped upwards along the hollow rods by this pump. At the same time, at the pump inlet, the pressure of the hydrostatic column of liquid, which depends on its height during the upward movement of the pump plunger, unloads the downhole pump unit from a part of the load equal to G = P _CR • f _PL , where P _CR - pressure at the pump equal to the pressure of the hydrostatic liquid column in the annular space 14, supporting the plunger of the deep pump 1 from the bottom when it moves up.

 Gas from the annular space at a predetermined height is sucked in by a gas depth pump 2, which has greater productivity compared to a liquid pump due to the double stroke of its piston. The gas injected into the tubing by this pump disperses the liquid exiting the hollow rods, which makes it possible to form a gas-liquid mixture with a much lower density, and therefore, significantly reduce the load due to the weight of the gas-liquid mixture lifted through the tubing.

 If the performance of the pump for pumping gas does not provide a rational volume of oil extracted from oil, then the gas volume is controlled by increasing or decreasing the gas pressure in the gas zone, which, while maintaining the optimal bottomhole pressure, i.e. maintaining the optimal fluid flow from the reservoir, providing a change in the depth of the pump, reducing or increasing the depth of the pump with a rational constant length of the annular space along which the degassed and demulsified fluid flows to the pump, allows you to adjust the rational performance of not only the gas pump, but also the pump pumping well fluid.

The proposed method for controlling the level of the gas-liquid mixture in the well and the installation for its implementation in comparison with existing methods have the following advantages:
1. Reduce the consumption of electricity spent on oil production through the use of potential types of energy available in the well produced itself (the difference in the densities of the components that make up the well production, changes in the physicochemical properties of the mixture).

 2. Increase the depth of the descent of the pumps and thereby expand the scope of the cheaper rod deep pumping method of oil production.

 3. They increase the efficiency of their operation by increasing the fill factor of the downhole pump when pumping liquids with various physical and structural properties, reducing the deformation of pipes and rods through the use of pressure retaining forces at the intake of the downhole pump.

Claims (3)

 1. The method of lifting a gas-liquid mixture from wells with sucker-rod pumps, which consists in lifting the liquid with a deep pump using the lifting energy of the gas and the pressure of the hydrostatic column of the gas-liquid mixture above the pump inlet, characterized in that liquid is supplied to the deep pump from top to bottom along the well isolated from the bottom annular space, having previously separated from the rising gas-liquid mixture in the annulus, when turning the direction of the liquid from ascending to descending, ha and, in the evacuated gas tubing and spread using its lifting power across the wellbore, and hydrostatic pressure of degassed liquid column located above the pump intake, relieve some of the load lifted by weight of the column of tubing downhole production.  2. The method according to p. 1, characterized in that the gas-liquid mixture supplied to the downhole pump is passed through the demulsion filters and the surfactant is fed into it in a narrowed passage formed by the gas separator-demulsifier body and tubing.  3. Installation for lifting a gas-liquid mixture from wells with rod pumps, comprising submersible pumps, suction and discharge valves, rod and pipe columns, gas bypass valves, characterized in that the installation has two pumps, one upper and one lower, with the latter having a single action with a ring the channel formed by its body and casing, and the receiving chamber, and the upper one is made with a double-acting piston, side suction and discharge gas bypass valves, and the upper pump is designed for gas pumping, and the lower one for pumping liquid, both pumps are interconnected by hollow rods and tubing and a gas separator-demulsifier is installed under the gas pump, consisting of a container for a surfactant, a filter housing with ring filters placed in it and passed through filters with tubes.