RU2282749C2 - Gas and gas-liquid mixtures injecting device - Google Patents

Abstract

FIELD: oil producing industry.

SUBSTANCE: invention relates to drilling, completion and operation of oil and gas wells. Proposed device includes displacement type hydraulic supercharger consisting of row of sections, compression chambers communicating with supercharger, each containing suction valve to deliver gas or gas-liquid mixture from independent source into chamber. Delivery valve communicating with consumer is arranged over suction valve. Pump to deliver feed liquid through suction valve of supercharger is installed to form hydraulic seal in compression chamber. Compression chambers are made in form of separate compression module connected by pipelines with hydraulic part of supercharger. Outer diameter of compression chamber (d_ch.out is found from expression

where d_w is thickness of chamber wall; d_s is diameter of supercharger; n is speed of supercharger shaft, min^-1; r is supercharger half travel;

where L is length of connecting rod; g is free fall acceleration. Diameter of pipeline (d_pl) connecting compression chamber with hydraulic part of supercharger complies to the following equation:

where α is angle between axis of pipeline and vertical. Capacity of said pipeline (V_pl) complies with relative V_pl<τ_sat·n·b_l-V_s where τ_sat is time of saturation of liquid with gas at working pressures;

where Q_l is flow rate of liquid; V_s is volume described by supercharger.

EFFECT: increased capacity, improved repairability.

4 cl, 1 dwg

Description

The present invention relates to the field of injection of gases and gas mixtures and, in particular, is a device with a volumetric hydraulic supercharger and compression chambers connected with it, which can find application in a number of technological operations in the process of hydrocarbon production: during drilling and development of oil and gas wells, in the implementation of secondary and tertiary methods of oil production, in the process of increasing the productivity of hydrocarbon wells and in a number of other cases in the process of residence and operation of wells of the indicated purpose.

A device is known consisting of a piston sectional pump having in each section a working cylinder with a working chamber formed therein, a suction valve, an additional chamber with a gas inlet valve and a discharge valve. The device also contains a feed pump for supplying a liquid with an overpressure equal to the pressure of the gas-liquid mixture or gas introduced into the additional chamber during the suction stroke of the piston pump. When the pump completes the pumping cycle, the gas or gas-liquid mixture is displaced through the discharge valve to the consumer (see ed. St. USSR No. 714044, class F 04 B 23/10, 1980).

For the prototype of the claimed device, a technical solution can be made according to the Certificate for a utility model of the Russian Federation No. 22204, class. F 04 B 19/06; 23/10 of March 10, 2002

In accordance with this technical solution, a device for injecting gas or a gas-liquid mixture includes a hydraulic pump of a volumetric type of reciprocating action (multi-plunger pump). The pump consists of several sections, each of which has a working cylinder, a plunger and a suction hydraulic valve. The device also includes compression chambers in communication with the respective sections of the supercharger. Each of the chambers contains a suction valve for communicating this chamber with an independent source of gas or gas-liquid mixture during the suction stroke. Above the suction valve in the compression chamber is placed a discharge valve in communication with the consumer. The device also includes a pump for supplying nutrient fluid from a separate source to create a water seal in the compression chambers. This pump is included in the concept of "liquid manifold" and is indicated by pos. 12, figure 1 of said certificate. for utility model No. 22204. The device also has a drive part with a crank mechanism.

During operation, at the suction stroke of the supercharger, the feed pump delivers liquid into the working chamber of the supercharger at a pressure equal to or slightly higher than the pressure of the gas or gas-liquid mixture supplied to the compression chamber, thus forming a water seal in the compression chamber, which prevents the penetration of gas from the compression chamber into the working chamber a supercharger chamber, which adversely affects the operation of the latter. The described technical solution has several disadvantages, to overcome which the claimed device is directed.

These disadvantages include:

1. the complexity of manufacturing and low maintainability of the device due to the fact that the compression chambers are directly connected to sections of the hydraulic supercharger;

2. the inability to install compression chambers without a significant alteration of the pump installation, which reduces the efficiency of work;

3. The outer diameter of the compression chambers is limited by the distance between the longitudinal axes of the supercharger sections, which limits the performance of the device.

In connection with the above, the main technical problem to be solved by the claimed technical device is to eliminate the above drawbacks and create such a device for pumping gases and gas-liquid mixtures, the design of which would provide its simpler manufacture, higher maintainability, increased efficiency and the possibility of increasing productivity due to the output of compression chambers beyond the design of the supercharger.

To solve the technical problem, the claimed device for injecting gases and gas-liquid mixtures includes a hydraulic blower of a volumetric type of reciprocating action, for example, a plunger pump consisting of several sections with a suction hydraulic valve in each section, compression chambers communicated with the corresponding sections of the blower, each of which contains a suction valve for communicating this chamber with an independent source of gas or gas-liquid mixture when performing a cycle suction and discharge valve disposed above the suction valve and the communication with the user, a pump for feeding nutrient liquid to create a hydraulic lock in the compression chambers and a drive part with a crank mechanism. Compression chambers are made in the form of a separate compression module, connected by pipelines to the hydraulic part of the supercharger. The external diameter of the compression chamber is determined from the ratio

d _{candidate of internal sciences} - outer diameter of the chamber;

d _c is the wall thickness of the chamber;

d _n - diameter of the supercharger;

n is the number of revolutions of the compressor shaft, min ^-1 ;

r is the half-stroke of the supercharger;

L is the length of the connecting rod;

g is the acceleration of gravity.

In addition, the diameter of the pipeline connecting each compression chamber to the hydraulic part of the supercharger satisfies the ratio

d _Tr - the diameter of the pipeline;

α is the angle between the axis of the pipeline and the vertical.

The volume of the pipeline connecting each compression chamber to the hydraulic part of the supercharger satisfies the ratio

V _tr <τ _cas · n · b _w -V _O.s. where

τ _cas - the time of saturation of the liquid with gas at operating pressures;

- объемная доля проточной жидкости,

- volume fraction of flowing fluid,

Q _W - flow rate;

V _op. - the volume described by the supercharger.

The possibility of implementing the inventive device is proved by the use of equipment for pumping gases and gas-liquid mixtures using piston pumps in domestic and foreign practice.

In particular, the above analogue and prototype are implemented in a number of domestic installations.

Technical features that are distinctive for the claimed device can be implemented using tools used in various fields of technology, including the drilling, development and operation of oil and gas wells. Distinctive features reflected in the claims are necessary and sufficient for its implementation, because provide a solution to the problem - the creation of such a device for injecting gases and gas-liquid mixtures, the design of which would ensure ease of manufacture, higher maintainability, increased operational efficiency and the possibility of increasing productivity.

In the future, the claimed device is illustrated by an example of its execution, schematically shown in the attached drawing, which shows a diagram of the inventive device for pumping gases and gas-liquid mixtures, side view showing one section of a hydraulic supercharger and a corresponding compression chamber.

A device for injecting gases and gas-liquid mixtures includes a hydraulic blower 1 volumetric type reciprocating action. It can be a piston or plunger pump consisting of several sections. In the hydraulic part 2 of each section of the supercharger there is a suction hydraulic valve 3 in communication with the pump for supplying the nutrient fluid 4 from the reservoir 5. The crank mechanism 6 is used to drive the pistons or plungers 7 of the supercharger 1. The compression chambers 8 are combined into a compression module 9. Each the compression chamber 8 includes a suction valve 10 for communicating with an independent source of gas or gas-liquid mixture (not shown) during the suction stroke and a pressure valve 11 located above the suction and communicated with the consumer (not shown).

The pump 4 serves to supply the nutrient fluid, creating a water lock 12 in the compression chamber, which prevents the penetration of gas into the hydraulic part of the supercharger. The compression chambers 8 of the compression module 9 are in communication with the hydraulic part of the supercharger by pipelines 13.

The operation of the device for pumping gases and gas-liquid mixtures is as follows.

A description of the work is given in relation to one section of the hydraulic supercharger 1. By means of a crank mechanism 6, the piston (plunger) 7 moves in the hydraulic part 2 of the supercharger during suction to the right. In this case, the feed pump 4 from the reservoir 5 supplies the feed fluid through the suction valve 3 to the hydraulic part 2 of the supercharger and through the pipe 13 the feed fluid enters the lower part of the compression chamber 8, forming a water trap 12, which prevents the penetration of gas simultaneously supplied through the suction valve 10 to the upper part of the compression chamber 8. When the piston (plunger) 7 moves to the left, the hydraulic lock 12 moves in the compression chamber 8 between the levels of the bottom dead center (BDC) and the top dead point (TDC), compressing the gas in the compression chamber to the desired value and displacing the compressed gas through the discharge valve 11 to the consumer. At the same time, a part of the hydraulic lock fluid is displaced through this valve, which is replaced by a feed pump (usually up to 5%) to the right during the next stroke of the supercharger.

In addition to the specified functions, the hydraulic lock fluid also has a gas cooling function. Due to the fluidity of the hydraulic lock, the “harmful” structural volume of the compression chamber is completely eliminated.

For the operation of the hydraulic lock, it is necessary that the maximum acceleration of the hydraulic lock liquid does not exceed the acceleration of gravity. In this case, bubbles of the compressed gas entering the water trap float. Otherwise, the bubbles are drawn inside the hydraulic seal by the negative force of Archimedes.

The acceleration of the liquid in the hydraulic lock is determined by the formula and in the working hydraulic lock must comply with the ratio

where r is the half-stroke of the supercharger,

- круговая частота,

- circular frequency

n is the number of revolutions of the compressor shaft, min ^-1 ,

L is the length of the connecting rod

d _n - the diameter of the supercharger,

d _K. - diameter of the flow part of the chamber,

g is the acceleration of gravity.

In the case of the traditional installation of chambers, the diameter of the flow part of the chamber is limited by the plunger distance and the chamber wall, the thickness of which increases when working in the high-pressure region:

d _K. = d _m.p. -2 d _c ;

where d _mp - plunger distance

d _c is the wall thickness of the chamber.

The maximum revolutions of the blower drive shaft in the case of traditional camera mounting are limited by the expression

Using the discharge pipe 13 and the output of the compression module beyond the design of the supercharger, it is possible to increase the speed of the supercharger shaft. The diameter of the chamber in this case is determined by the ratio

where d _q.v. - the outer diameter of the chamber.

In the inlet pipe is the oscillatory movement of the valve fluid. For the device to work, it is necessary that no negative accelerations occur in the pipeline.

In the case when the pipeline is deviated from the vertical by an angle α, the condition is written as follows:

where d _Tr - the diameter of the tube,

α is the angle between the axis of the tube and the vertical.

The presence of horizontal sections of the pipeline is allowed, but undesirable.

In the case of operation of the device with the separation of the flowing fluid, restrictions are imposed on the volume of the pipeline. This is due to the fact that at high operating pressures, the compressed gas is actively dissolved in the hydraulic lock fluid and this gas is lost during liquid separation. The replacement time of the working fluid (usually 12-15 s) should be significantly less than the time of gas dissolution in the fluid (usually ~ 1-2 min).

The volume of the pipeline must satisfy the ratio

V _tr <τ _cas · n · b _w -V _O.s.

where V _Tr - the volume of the pipeline;

τ _cas - the time of saturation of the liquid with gas at operating pressures;

- объемная доля проточной жидкости,

- volume fraction of flowing fluid,

Q _W - flow rate;

V _op. - the volume described by the supercharger.

Thus, the advantage of the claimed device is:

1) more simple manufacture of the device;

2) better maintainability, as there is no direct connection of the compression chambers to the supercharger sections;

3) better operational efficiency when using the device (compression chambers can be installed with most operating pumping units, for example from reservoir pressure maintenance systems, without significant alteration of the units);

4) the possibility of increasing the productivity of the device (since the diameter of the compression chambers is not limited by the thickness of their walls and the distance between the longitudinal axes of the sections of the supercharger).

Claims (4)

1. A device for injecting gases and gas-liquid mixtures, comprising a reciprocating hydraulic volumetric blower, for example, a plunger pump consisting of several sections with a suction hydraulic valve in each section, compression chambers in communication with respective sections of the supercharger, each of which contains a suction a valve for communicating this chamber with an independent source of gas or gas-liquid mixture during the suction stroke, and a discharge valve placed on hell by a suction valve and communicated with the consumer, a pump for supplying nutrient fluid to create a water seal in the compression chambers and a drive part with a crank mechanism, characterized in that the compression chambers are made as separate compression modules connected by pipelines to the hydraulic part of the supercharger. 2. A device for injecting gases and gas-liquid mixtures according to claim 1, characterized in that the outer diameter of the compression chamber is determined from the ratio

where d _with - the wall thickness of the chamber; d _n - diameter of the supercharger; n is the number of revolutions of the compressor shaft, min ^-1 ; r is the half-pass of the supercharger,

L is the length of the connecting rod; g is the acceleration of gravity. 3. The device for injecting gases and gas-liquid mixtures according to claim 1, characterized in that the diameter of the pipeline connecting each compression chamber to the hydraulic part of the supercharger satisfies the ratio

where d _Tr - the diameter of the pipeline; α is the angle between the axis of the pipeline and the vertical. 4. A device for injecting gases and gas-liquid mixtures according to claim 1, characterized in that the volume of the pipeline connecting each compression chamber to the hydraulic part of the supercharger satisfies the ratio V _Tr <τ _us · n · b _W -V _O.s. , where V _Tr - the volume of the pipeline; τ _us - the time of saturation of the liquid with gas at operating pressures;

- volume fraction of flowing fluid; Q _W - flow rate; V _op. - the volume described by the supercharger.