RU63472U1 - ADJUSTABLE EJECTOR (OPTIONS) - Google Patents

Abstract

The utility model relates to the field of inkjet technology and can be used to eject gas from low-rate gas condensate wells and supply it to the interfield gas pipeline while ensuring the required operating mode of the wells. The objective of the utility model is to increase operational reliability, expand functionality by providing active gas supply to both the central and peripheral nozzles and, as a result, increase productivity. The adjustable ejector according to option 1 includes a housing with medium supply pipes made of a running assembly, a distribution block, an interchangeable mixing chamber and forming an annular charge nozzle with a diffuser, and also includes through channels, means for regulating the ejector, with an internal hole the central nozzle is made tapering with a Mach number of not more than 1.5, and the outer surface of the central nozzle forms an annular Laval nozzle pass with the inner surface of the insert sleeve vnogo stream. The adjustable ejector according to option 2 is characterized by the presence of a check valve located in the distribution block, while the outer surface of the central nozzle and the inner surface of the insert sleeve are capable of forming, when combined, a tapering peripheral nozzle with a Mach number of not more than 1.5. 2 nz f-ly, 5 ill.

Description

The utility model relates to the field of inkjet technology and can be used to eject gas from low-rate gas condensate wells and supply it to the interfield gas pipeline while ensuring the required operating mode of the wells.

The prototype is an ejector comprising a housing containing passports for supplying a passive and active medium, made of pipes serially connected to each other by means of flanges, in the coaxially made bores of which in the axial direction a running unit is installed, consisting of a running nut with a flywheel, bearing mounted on it, retractable spindle with a pointer mounted on it perpendicular to the scale mounted on the housing, while the retractable spindle is rigidly connected to the distribution block, on the outside The springs of which have O-rings installed, including passive medium supply channels, a non-return valve installed in the low-pressure chamber, and a passive nozzle, an adapter, the outer surface of which is provided with a sealing ring, which together with the plug-in sleeve form a supersonic Laval nozzle with an oblique with the outer conical surface of the passive nozzle cut, while the chamber of the supply of the active medium, formed in the bore inside the ejector body, is in communication with the means for measuring pressure, located on the outside part of the ejector body, and a removable mixing chamber, rigidly mounted in the adapter, forms an annular charge nozzle with a diffuser,

while inside the diffuser in the axial direction from the inlet to the outlet cross-section, through channels are made, equally spaced in circle diameter, a mixing chamber and a diffuser [Patent for PM No. 40410, IPC ⁷ F04F 05/48, publ. 09/10/2004].

The main disadvantage of the described device is the significant consumption of active gas necessary to ensure the operation of the ejector, as well as the danger of the distribution block moving towards the running unit due to the high working pressure created inside the ejector.

The objective of the utility model is to eliminate the disadvantages of the prototype in order to increase reliability in operation, expand functionality by providing an active gas supply to both the central and peripheral nozzles and, as a result, increase productivity.

The technical result is manifested in a decrease in the consumption of active gas, an increase in the intensity of mixing of the pumped and pumped flows, as well as in the expansion of the arsenal of technical means.

In the embodiment with the supply of the active medium through the central nozzle, the task is set in an adjustable ejector, which includes a housing containing medium supply pipes made of pipes connected in series with each other by means of flanges, a running assembly consisting of a running nut with a flywheel, bearing mounted on it, retractable spindle with a pointer mounted on it perpendicular to the scale mounted on the housing, distribution block, o-rings, central nozzle, plug-in sleeve, interchangeable chambers for mixing, rigidly mounted in the adapter and forming an annular nozzle of pressurization with a diffuser, while inside the diffuser in the axial direction from the inlet to the outlet cross-section there are through channels equally spaced along the circumference, it is decided that between the pipe serving as the chassis of the running unit and the pipe in which the distribution block is mounted, additionally

a protective flange is installed, made with a through hole for moving the spindle, a thrust nut and protrusions that allow you to install and fix the protective flange between the counter flanges of the adjustable ejector body, a sleeve is mounted in the distribution block, while the inner hole of the central nozzle is made tapering with a Mach number of not more than 1 , 5, and the outer surface of the central nozzle forms an annular Laval nozzle of the passive flow with the inner surface of the insert sleeve.

In the embodiment with the supply of the active medium through the peripheral nozzle, the task is set in an adjustable ejector, including a housing containing medium supply nozzles made of nozzles serially connected with each other by means of flanges, a running assembly consisting of a running nut with a flywheel, bearing mounted on it, retractable spindle with a pointer mounted on it perpendicular to the scale mounted on the housing, distribution block, o-rings, center nozzle, plug-in sleeve, interchangeable cam mixing unit, rigidly installed in the adapter and forming an annular charge nozzle with a diffuser, while through the diffuser there are made through channels in the axial direction from the inlet to the outlet cross-section, equally spaced in circumference, by the fact that between the nozzle serving as the body of the running unit and the nozzle in which the distribution block is mounted, a protective flange is additionally installed, made with a through hole for moving the spindle, a thrust nut and protrusions that allow installation and fixing Rowan protective flange body between the opposing flanges adjustable ejector distribution unit is provided with a nonreturn valve, wherein the outer surface of the central nozzle and the inner surface of the insertion sleeve are formed so that when combined form a tapering peripheral nozzle with a Mach number less than 1.5.

Salient features of the claimed utility model in comparison with the prototype are:

1) version with active medium supply through the central nozzle:

- between the nozzle serving as the chassis of the running unit and the nozzle in which the distribution block is mounted, a protective flange is additionally installed, made with a through hole for moving the spindle from the thrust nut and protrusions that allow you to install and fix the protective flange between the oncoming flanges of the adjustable ejector body;

- a sleeve is mounted in the distribution block, while the inner hole of the central nozzle is made tapering with a Mach number of not more than 1.5, and the outer surface of the central nozzle forms a ring Laval nozzle of the passive flow with the inner surface of the insertion sleeve;

2) version with active medium supply through a peripheral nozzle:

- between the nozzle that serves as the chassis of the running unit, and the nozzle in which the distribution block is mounted, a protective flange is additionally installed, made with a through hole for moving the spindle from the thrust nut and protrusions that allow you to install and fix the protective flange between the counter flanges of the adjustable ejector body, in the distribution the unit is mounted sleeve;

- the distribution block is equipped with a check valve, while the outer surface of the central nozzle and the inner surface of the insertion sleeve are made in such a way that when combined they form a tapering peripheral nozzle with a Mach number of not more than 1.5.

The above set of essential distinguishing features was unknown to us from the sources of patent and scientific and technical information,

those. The utility model meets the patentability condition “Novelty”.

As for the “industrial applicability”, the utility model also meets this condition of patentability, since for its implementation we have developed the necessary technical documentation (including working drawings), and the operation of the adjustable ejector was modeled by step-by-step drawing, that is, we can state that the claimed utility model in any of the embodiments can be easily implemented at specific production facilities.

Figure 1 shows an adjustable ejector according to option 1), a longitudinal section; figure 2 shows an adjustable ejector according to option 2), a longitudinal section; figure 3 is a remote section A in figure 1, 2; figure 4 - remote section B in figure 1; figure 5 - remote section In figure 2.

According to option 1 (Fig. 1), the adjustable ejector includes a housing 1, which contains medium supply pipes 2 and 3, made of conduits 4 connected in series with each other by means of flanges, a travel assembly consisting of a travel nut 5 with a flywheel 6 mounted on it and a bearing 7, a sliding spindle 8 with a pointer 9 mounted on it perpendicular to the scale 10, mounted on the housing 1, the distribution block 11, the sealing rings 12, the central 13 nozzle, the insert sleeve 14, a removable mixing chamber 15, rigidly mounted in the adapter 16 and form an annular charge nozzle 18 with a diffuser 17, while inside the diffuser 17 in the axial direction from the inlet to the outlet section, through channels 19 are made, equally spaced in circumference, between the nozzle 20, which serves as the chassis of the chassis, and the housing 1, in which the distribution block is mounted 11, a protective flange 21 is additionally installed, made with a bore 22 for moving the spindle 8 with the thrust nut 23 and the protrusions 24, allowing to install and fix the protective

a flange 21 between the opposing flanges of the adjustable ejector body, a sleeve 25 is mounted in the distribution block 11, while the inner hole of the central nozzle 13 is tapering with a Mach number of not more than 1.5, and the outer surface of the central nozzle 13 forms an annular nozzle with the inner surface of the insert sleeve 14 Laval passive flow 26.

In option 2 (FIG. 2), the adjustable ejector includes a housing 1, which contains medium supply pipes 2 and 3, made of 4 pipes serially connected to each other by means of flanges, a travel assembly consisting of a travel nut 5 with a flywheel 6 mounted on it, and a bearing 7, a sliding spindle 8 with a pointer 9 mounted on it perpendicular to the scale 10, mounted on the housing 1, the distribution block 11, the sealing rings 12, the central nozzle 13, the insert sleeve 14, the removable mixing chamber 15, rigidly mounted in the adapter 16 and form an annular charge nozzle 18 with diffuser 17, while inside the diffuser 17 in the axial direction from the inlet to the outlet section, through channels 19 are made, equally spaced in circumference, between the nozzle 20 serving as the chassis of the chassis and the housing 1 in which the distribution block is mounted 11, a protective flange 21 is additionally installed, made with a bore 22 for moving the spindle 8 with the thrust nut 23 and protrusions 24, allowing to install and fix the protective flange 21 between the counter flanges of the housing With an adjustable ejector, the distribution block 11 is equipped with a check valve 25, while the outer surface of the central nozzle 13 and the inner surface of the insert sleeve 14 are made in such a way that when combined they form a tapering peripheral nozzle 26 with a Mach number of not more than 1.5.

The work of an adjustable ejector according to option 1.

Active gas flows through pipe 2 to the distribution block 11,

the central nozzle 13, the mixing chamber 15. Passive gas moves along the pipe 3 along the annular gap into the mixing chamber 15. As the central nozzle 13 approaches the mixing chamber 15, the amount of sucked gas increases, as the average passive flow rate increases.

At the inlet cross-section of the diffuser through the annular nozzle of boost 18, the ejected medium is pressurized with a higher-pressure gas discharged through the through channels 19, which suction the boundary layer near the outlet cross-section of the diffuser 17, which allows shifting the flow separation and reducing losses from unevenness. The axial movement of the central nozzle 13, using the elements of the running unit, changes the critical section (geometric parameter) of the Laval ring nozzle of the passive flow 26. The provided possibility of replacing the mixing chamber 15, which does not require complete disassembly of the adjustable ejector, allows the selection of the optimal length of the mixing chamber 15.

The work of an adjustable ejector according to option 2.

Active gas through the pipe 3 enters the housing 1 of the adjustable ejector and, passing through the tapering peripheral nozzle 26 formed between the central nozzle 13 and the insert sleeve 14, is discharged at a high speed to a certain pressure, the value of which depends on the ejector settings. Under the influence of the pressure difference in the pipeline (loop) and behind the nozzle, the passive gas is sucked into the pipe 2, passes through the channels of the distribution block 11, through the check valve 25, the central nozzle 13 into the mixing chamber 15. In the mixing chamber 15, the jet of active gas interacts with the ejected medium and, accelerating it, carries away into the diffuser 17, where the resulting mixture is compressed. As the central nozzle 13 approaches the insertion sleeve 14 of the mixing chamber 15, the critical section of the peripheral nozzle 26, the active flow rate, and the ejector operating mode change.

Claims (2)

1. An adjustable ejector comprising a housing containing media supply nozzles made of nozzles serially connected to each other by means of nozzle flanges, a travel assembly consisting of a travel nut with a flywheel mounted on it, a bearing, a retractable spindle with a pointer mounted on it perpendicular to the scale, fixed to the housing, distribution block, o-rings, central nozzle, plug-in sleeve, removable mixing chamber, rigidly mounted in the adapter and forming a ring nozzle with diffuser and, while inside the diffuser in the axial direction from the inlet to the outlet section, through channels are made, equally spaced in circumference, characterized in that between the nozzle serving as the chassis of the running unit and the nozzle in which the distribution block is mounted, a protective flange is additionally installed, made with a through hole for moving the spindle, a thrust nut and protrusions that allow you to install and fix the protective flange between the counter flanges of the casing of the adjustable ejector, in distribution elitelny unit mounted sleeve, wherein the inner bore of the central nozzle formed tapering with a Mach number less than 1.5, and the outer surface of the central nozzle forms with the inner surface of the insertion sleeve annular Laval nozzle passive flow. 2. An adjustable ejector comprising a housing containing medium supply pipes made of pipes serially connected to each other by means of flanges, a travel assembly consisting of a travel nut with a flywheel mounted on it, a bearing, a retractable spindle with a pointer mounted on it perpendicular to the scale, fixed to the housing, distribution block, o-rings, central nozzle, plug-in sleeve, removable mixing chamber, rigidly mounted in the adapter and forming a ring nozzle with diffuser and, while inside the diffuser in the axial direction from the inlet to the outlet section, through channels are made, equally spaced in circumference, characterized in that between the nozzle serving as the chassis of the running unit and the nozzle in which the distribution block is mounted, a protective flange is additionally installed, made with a through hole for moving the spindle, a thrust nut and protrusions that allow you to install and fix the protective flange between the oncoming flanges of the adjustable ejector body, The diesel unit is equipped with a check valve, while the outer surface of the central nozzle and the inner surface of the insert sleeve are made in such a way that, when combined, they form a tapering peripheral nozzle with a Mach number of not more than 1.5.