RU2610484C9 - Method and device for adjustable injection of fluid to layers with automated measuring of process parameters - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention falls into the area of the maintenance of the reservoir pressure on the multilayer field and can be applied at the dual injection of fluid to one or more layers of one well, as well as in a number of cases it may be applied to control, investigate and cut-off of the injection of fluid to the layers in the deep disposal well. A packaging arrangement, including a socket or a shank, a lower packer, a disconnecter, a device for measuring the parameters of the injected fluid, a pumping distribution device, upper packer, an anchor, a disconnecter and an extension tool are lowered to the well on the flow column - FC. Along the immersible downhole equipment the controlling cable is routed (geophysical and/or fiberglass cable or cable of other type) to measure the parameters of the injected fluid. If necessary to measure the parameters of the injected fluid, the extractible part of the pumping distribution device is extracted and the diameters of the flow beans are modified, or, if necessary to disable the pumping of any layer, an appropriate end plug is installed instead of the flow bean. On the device chassis on the outer lateral face there is a linear bore back in the form of a channel for laying the controlling cable from the device for measuring the parameters of the injected fluid, as well as a flow channel of the diffuser is made in the form of a nonconvergent conical body, developing into a cylinder. A technical result is to improve the effectiveness of the device for measuring the parameters of the injected fluid.

EFFECT: invention provides the possibility by means of one device to implement the adjustable injection of fluid to the layers and using, at least one of the measuring device to perform the measurements of the basic parameters of the fluid injection.

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Description

The invention relates to the field of maintaining reservoir pressure in multilayer fields and can be used for simultaneous and separate injection of fluid into one or more formations of one well, and in some cases can also be used to regulate, study, and cut off fluid injection into formations in an injection well. It provides "the ability to use a single injection distribution device to carry out an adjustable injection of fluid into the reservoirs and using at least one measuring device to measure the main parameters of the fluid injection.

A known installation for simultaneous-separate injection of water into the reservoirs, selected as an analogue, including a column of elevator pipes with packers and couplings with axial and radial channels and a removable plug. The removable plug descends from the mouth on the draft and is made with the possibility of tight interaction with the axial channels of the couplings. The removable plug is made by the team and consists of plungers that are connected by rods and interact with the corresponding axial channels of the couplings and is constantly located in the well. Moreover, the length of rods, bushings of couplings and plungers, their number, as well as the number of holes in the bushings of the couplings are selected with the possibility of selective overlapping by the plungers of radial channels in the corresponding bushings of the couplings without lifting the plug to the surface (RU No. 2436934 C1, IPC E21B 43/00, prior. 06/01/2010).

A disadvantage of the known installation is the difficulty in selecting the length of rods, bushings of couplings and plungers, their number, as well as the number of holes in the bushings of the couplings, depending on the number of layers and the switching options necessary for their operation. The disadvantages include the large metal consumption, as well as the inability to use geophysical instruments in this installation.

A well-known well installation, selected as an analogue, including tubing pipes lowered into the production string — tubing with downhole oval chambers and / or central nipples having transverse channels and a seat with a removable valve in the form of a housing with radial, axial and hydraulically connected to cross channels, seals and retainer. A control element is installed inside the housing, connected with the rod of the locking element. An additional pipe string is installed to a depth below the unsealed portion of the production string; in the annular space formed between the pipe strings, a cement bridge and / or one or more hermetically isolating cavities of disconnectors are installed, while tubing is installed inside the additional pipe string, and part of the borehole surface the oval chamber above the seat of the removable valve is pressed from both sides into the internal cavity and / or the body of the removable valve in the central nipple flax with internal longitudinal non-axial through channels, hydraulically communicating tubing cavities above and below the central nipple (RU No. 2131017 C1, IPC ЕВВ 43/00, prior. 08.07.1997).

A disadvantage of the known installation is the need for a large number of tripping operations to replace removable valves, while both the descent and lifting of the valves is carried out only using special cable technology.

Known three-packer installation, selected as an analogue, containing equipment mounted in the production string of the well on the tubing string. The equipment includes upper, middle and lower packers, a through-type nipple, a funnel with a ball, circulation valves, mechanical heat compensators, a jet pump and a non-through-out nipple with the possibility of installing a blind plug or fitting. Each of the packers has an individual installation and lifting scheme. The upper packer is made with a hydraulic unit and axially lifted upward after cutting the power pins, the middle packer is of mechanical action with a support unit and rotary-axial removal, the lower packer is of mechanical action with a rotary-axial installation and removal. The lower and middle packers can be lifted from the well only after rotation of the tubing string, and the upper packer after tightening the tubing string, taking into account the regulated effort for it. The packers are double-sided and can be independently placed in a fixed place in the production casing (RU No. 77899 U1, MPK Е21В 43/14, Е21В 33/12, prior. May 26, 2008).

A disadvantage of the known installation is the need for a large number of tripping operations to replace the fitting inserts installed in the circulation valves.

It is known equipment for simultaneous-separate injection of water into two layers through one well selected as an analogue, containing a pipe string with a packer installed between the layers, above which there is a cross coupling that hydraulically connects the internal cavity of the pipes to the over-packer annulus of the well. A check valve is integrated in the hydraulic channel of the cross-coupling, eliminating the flow of water from the borehole into the pipe cavity. The hydraulic channel of the cross-coupling has a saddle, to shut off which a shut-off element is lowered from the wellhead, closing the saddle by a shut-off element eliminates the flow of water from the pipes into the borehole annulus. The locking element can be made of material with a density lower than the density of water injected into the well (RU No. 59140 U1, IPC ЕВВ 43/16, prior. 06/19/2006).

The disadvantages of the known equipment include the fact that the regulation of injection is performed only on the upper layer. Moreover, the regulation mechanism is not reliable enough, because in case of intensive injection of water into the formation, the elastic properties of the return spring may be lost. The disadvantages also include the lack of an upper packer in the equipment necessary to protect the pipe string from the effects of high pressure injection of the working agent into the reservoir.

A known method of simultaneous-separate injection of fluid into the reservoirs with the ability to measure the parameters of the injected fluid and installation for its implementation (RF application No. 2014126833), selected as an analogue, which includes the descent into the well on the pipe string of the installation, consisting of a funnel-centralizer, a lower packer , sub-centralizer, injection distribution device, top packer, extension cord. Install the lower and upper packers, pressurize the annular space above the lower and upper packers, supply fluid to the pipe string, determine the fluid flow rate in the reservoirs, compare the actual fluid flow rate for the reservoirs with the given values, raise the extracted part of the injection distribution device to the surface with their difference fishing tool on a geophysical cable, wire or coiled tubing installation, set in the seats of the extracted part of the upper distribution injection device it and the lower fittings, the extractable part of the injection distribution device is lowered into the pipe string on the geophysical cable, wire or coiled tubing is installed before it is inserted into the housing of the injection distribution device, the fluid is pumped in an adjustable manner, the installation is lifted at the end of work. The injection distribution device is equipped with an upper autonomous pressure gauge installed up to the upper nozzle, a middle autonomous pressure gauge installed under the upper nozzle and a lower autonomous pressure gauge installed under the lower nozzle, while the upper and lower nozzles are located in the removable part of the injection distribution device with the possibility of extracting both nozzles for one round trip. The invention allows to obtain information about the magnitude of the liquid injection pressure and reliable data on the injection mode.

The disadvantage of this method is the lack of the ability to measure injection costs in real time, to fix them in the independent memory of the station for monitoring parameters and / or remotely from an electronic computer and to retrieve information with archive data from the station for monitoring parameters. Another disadvantage is the lack of temperature readings of the injected fluid. A disadvantage of the known injection control device is the absence of a figured groove in the housing of the injection distribution device for pulling a geophysical, fiber optic or other type of cable along it.

The closest technical solution, according to the set of coinciding features and the achieved technical result, taken as a prototype, is a method and device for controlled injection of fluid into the reservoirs (RF patent No. 2495235, ЕВВ 43/14; the patent holder of this patent is the applicant), which includes the descent into the well on the tubing string of an arrangement including a lower packer, a disconnector, an injection distribution device, an upper packer, a disconnector. The lower part of the layout is equipped with a funnel or shank, and the upper part of the layout is equipped with an extension. A centralizer sub is installed above the lower and upper packers. Install and pressure packers. Lower the depth meter with the plug above the last seat. They supply fluid to the tubing, determine the total fluid flow. Lower the cork into the seat, supply fluid to the tubing, determine the flow rate of the fluid pumped into the lower layer. Subtract it from the total flow rate and find the flow rate of the fluid pumped into the upper reservoir. The actual fluid flow rates for the formations are compared with predetermined values. With their difference, the extracted part of the injection distribution device is lifted to the surface. Install the upper and lower fittings in the seats. The extracted part of the injection distribution device is lowered into the tubing until it fits into the body of the injection distribution device. Carry out adjustable injection in the reservoirs. To isolate one of the layers, a plug is installed instead of the fitting. At the end of the work, the installation is hoisted. The injection distribution device includes a body part consisting of a nipple with several through channels, a body and an adapter sleeve, an extractable part consisting of an upper and lower sleeve and a diffuser. Seats under the upper and lower fittings or caps are made in the upper sleeve and diffuser. In the upper sleeve there is a seat for the cork. The upper and lower central channels, diverging and converging channels are made in the lower sleeve. The invention allows using a single device to carry out an adjustable injection of fluid into the reservoirs with measurements of the costs of the reservoirs.

The disadvantage of this method is the lack of the ability to measure injection costs in real time, to fix them in the independent memory of the station for monitoring parameters and / or remotely from an electronic computer and to retrieve information with archive data from the station for monitoring parameters. Another disadvantage is the impossibility of monitoring the tightness of the packer-tubing string system — control device, the lack of pressure drop in the tubing, in the annulus and the temperature of the injected fluid. A disadvantage of the known injection control device is the absence of a figured groove on the housing of the injection distribution device for pulling a geophysical, fiber optic or other type of cable along it, as well as the flow channel of the diffuser of the extractable part of the injection distribution device, so that smoothing of liquid pulsations after the nozzle does not occur for the purpose increasing the accuracy of the measurement on the device for measuring and reducing the erosive effect of the fluid flow on the tubing wall.

The problem solved by the invention is the implementation of a controlled injection of fluid into the reservoirs using an injection distribution device and at least one device for measuring the parameters of the injected fluid with automated measurement of pressure, flow rate, fluid temperature and other process parameters into each of the reservoirs in real time time, processing and passage of geophysical instruments through an open passage channel to a device for measuring the parameters of the injected fluid.

The specified technical result is achieved by the fact that:

- an apparatus for measuring the parameters of the injected fluid is installed to measure the parameters of the injected fluid, an anchor is installed above the upper packer, a control cable is laid along the submersible downhole equipment from the apparatus for measuring the parameters of the injected fluid to the parameter monitoring station located at the wellhead, the fluid is supplied to tubing cavity, measure the main parameters of fluid injection and other process parameters into one of the layers using a direct method measurement, and on the other layer - indirect: determine the main process parameters in one of the layers, on the other layer, the process parameters are determined by subtracting the measured flow rate from the device for measuring the parameters of the injected fluid from the total flow rate measured by the wellhead flow meter, if necessary, pumping only to the bottom the layer is lifted the extracted part of the injection distribution device to the surface, a plug is installed in the seat of the upper sleeve, and the lower fitting is installed t into the diffuser seat, lower the retrievable part of the injection distribution device into the tubing string until it fits into the body of the injection distribution device, if it is necessary to pump only the upper distribution layer, lift the extracted part of the injection distribution device to the surface, install the upper fitting into the seat the upper sleeve, and the plug in the seat of the diffuser, lower or discard the extracted part of the injection distribution device in the tubing before it fits into the housing part of the injection distribution device;

- the layout above the lower packer is equipped with a device for measuring the parameters of the injected fluid;

- the anchor perform the mechanical or hydraulic principle of operation with grooves along the body;

- on the device’s body on the outer side surface there is a longitudinal groove in the form of a channel, and also the passage channel of the diffuser is made in the form of a diverging cone passing into the cylinder.

Adjustable fluid injection is carried out by installing a nozzle insert with adjustable fittings.

Automated measurement of process parameters of controlled injection, including pressure, flow rate, fluid temperature and other process parameters into each of the strata, is carried out in real time due to the constant transmission of data from the device for measuring the parameters of the injected fluid to the monitoring station located on wellhead, using a control cable laid along the submersible downhole equipment from the device for measuring the parameters of the injected fluid to the station Control parameters.

Provided that the extracted part of the injection distribution device is extracted, it is possible to pass the geophysical instruments through an open passage channel to the device for measuring the parameters of the injected liquid and process the results.

The layout diagram of underground equipment for controlled fluid injection with automated measurement of process parameters in the reservoirs is shown in FIG. 1. The frontal section and horizontal section AA of the injection distribution device with a longitudinal groove in the form of a channel for a control cable, with a removable insert and the direction of fluid flow into the lower layer are shown in FIG. 2. A profile section of an injection distribution device with a longitudinal groove in the form of a channel for a control cable with a removable insert and the direction of fluid flow into the upper formation is shown in FIG. 3.

The installation includes a layout of underground equipment lowered into a well 1 (Fig. 1) on a tubing string 2, including a funnel 11 or a liner (not shown in Fig. 1), a lower packer 3, a disconnector 4, a device for measuring the parameters of the injected fluid 5, injection distribution device 6, upper packer 7, anchor 8, disconnector 9, extension cord 10. The lower packer 3 is made of a mechanical principle of operation and is mounted above the funnel 11 or the shank. Disconnectors 4 and 9 are installed above the lower packer 3 and the upper packer 7 with the armature 8, respectively. Disconnectors 4 and 9 can be performed mechanical or hydraulic principle of operation and are used to disconnect the tubing string 2 from the lower packer 3 and the upper packer 7, respectively, in case of sticking. Above the lower packer 3 and under the upper packer 7, in a particular case, centralizers (not shown) are installed. A device for measuring the parameters of the injected fluid 5 is located in the casing (not shown) above the disconnector 4 and is connected via a control cable 13 to a monitoring station for parameters 12 located at the wellhead 1. The device for measuring the parameters of the injected fluid 5 is used for automated measurement of the main parameters fluid injected and other process parameters in real time. Above the device for measuring the parameters of the injected liquid 5, an injection distribution device 6 is installed, which serves to regulate the volume of liquid injected into the lower layer 14 and the upper layer 15, as well as to isolate one of the layers if necessary. Next, the upper packer 7 is installed, made with the possibility of laying and sealing the input-output of the control cable 13 and with emphasis on the lower packer 3. An anchor 8 is installed above the upper packer 7, on the case of which grooves for laying the control cable 13 are made. Next, a disconnector 9 is installed. An extension cord 10 is installed in the upper part of the arrangement (in FIG. 1, an extension cord 10 is mounted above the disconnector 9) either through a certain number of sections of the tubing string 2 or directly under the faceplate (not shown in FIG. 1). An extension cord 10 is used to tightly connect the upper packer 7 to the tubing string 2 and to compensate for the axial movements of the tubing string 2 that occur during fluid injection. A control cable 13 (geophysical and / or fiber optic or other type of cable) from one and / or several devices for measuring the parameters of the injected fluid 5 to the monitoring station 12 located at the wellhead 1 was laid along the downhole equipment.

The distribution device for injection 6 (Fig. 1) consists of housing and extractable parts. The body part (Fig. 2) consists of interconnected nipples 16, the housing 17 and the adapter sleeve 18. Several through channels 19 are made in the nipple 16. A removable part is inserted into the body part, consisting of top to bottom of the upper sleeve 20, the lower sleeve 21 and a diffuser 22. On the lower sleeve 21 installed upper 23 and lower 24 sealing nodes. The upper sealing assembly 23 is secured from below by a nut 25. The lower sealing assembly 24 is bounded from above by an abutment 26, which acts as a limiter for the movement of the extracted part when it fits into the housing. A chamber 27 is formed between the housing and the parts to be removed. In the upper sleeve 20 and the diffuser 22 there are seats 28 and 29 under the upper 30 and lower 31 fittings or plugs (not shown in FIGS. 2, 3). Also in the upper sleeve 20 there is a seat 32 for the crimping valve (not shown in FIG.). In the lower sleeve 21, an upper central channel 33 is formed, branching to form several diverging channels 34 (Fig. 3). The diverging channels 34 are connected with the chamber 27 and with the through channels of the nipple 19. In the lower sleeve 21 there are also several converging channels 35 forming the lower central channel 36. The lower central channel 36 is in communication with the passage channel 37 of the diffuser 22. On the device side the surface has a longitudinal groove 38 (Fig. 2, section A-A) in the form of a channel for laying a control cable 13 from one and / or several devices for measuring the parameters of the injected fluid 5 to the station for monitoring parameters 12, position worn at the wellhead 1. The passage channel 37 of the diffuser 22 is made in the form of a diverging cone, passing into the cylinder, to smooth out the pulsations of the liquid after the nozzle 31, to increase the accuracy of automated metering on the device for measuring the parameters of the injected fluid 5 and to reduce the erosive effect of the fluid flow on the column walls Tubing 2.

The implementation of the method is described in the description of the equipment.

Before the installation is launched, wells 1 are modeled (Fig. 1) and the casing walls are cleaned with scrapers (scrapers) (not shown in Fig. 1), and then the wellbore is flushed 1. The installation is assembled in the following sequence: funnel 11 or liner, lower packer 3, a disconnector 4, a device for measuring the parameters of the injected fluid 5, an injection distribution device 6, an upper packer 7, an anchor 8, a disconnector 9. An extension cord 10 is installed in the upper part of the arrangement (in FIG. 1, an extension cord 10 is installed above the disconnector 9) or black a certain number of sections of the tubing 2, or directly under the faceplate (FIG. 1, not shown). In a particular case, centralizers are installed over the lower 3 and upper 7 packers. Then the installation is lowered on the tubing string 2 into the wellbore 1 to a certain depth. The installation is lowered either without a removable part of the injection distribution device 6, when an open passage channel is required for processing and passage of geophysical equipment, or together with a removable part of the injection distribution device 6, when there is no need for an open passage channel. When assembling and lowering the installation into the wellbore 1, simultaneously, a control cable 13 (geophysical and / or fiber-optic or other type of cable) is laid along the submersible borehole equipment from one and / or several devices for measuring the parameters of the injected fluid 5 to the monitoring station 12 located at the wellhead 1. Then the wellhead is equipped with wellhead fittings. Install and then test the lower packer 3 and the upper packer 7, which is capable of laying and sealing the input-output of the control cable 13. Fluid is supplied to the cavity of the tubing string 2. The fluid enters the lower reservoir 14, passing through converging channels 35 (Fig. 2), the lower central channel 36, the lower fitting 31 and the passage channel 37 of the diffuser 22. The fluid enters the upper formation 15, passing through the upper fitting 30, the upper central channel 33 and the diverging channels 34 (Fig. 3), and then through the chamber 27 through channels 19. Amount molecular weight flow rate entering the two layers, wellhead measured flow meter (not shown). The main parameters of fluid injection (pressure in the tubing string 2, pressure in the annulus, temperature of the injected fluid, fluid flow rate) injected into the lower reservoir 14 and into the upper reservoir 15, in the particular case either into the lower reservoir 14 or the upper reservoir 15, and other process parameters are determined and transmitted to the station for monitoring parameters 12 (Fig. 1) and / or a central electronic computer (not shown) via a control cable 13 or by any other method. Measure the main parameters of the fluid injection and other process parameters into one of the layers using the direct method of measurement, and indirectly by the other layer: determine the main parameters of the process into one of the layers, determine the process parameters by subtracting the measured flow rate from the device for measuring the parameters of the pumped liquid 5 from the total flow rate measured by the wellhead flowmeter. The actual fluid flow rates for the lower 14 and upper 15 layers are compared with the given values. If the actual costs differ from the set values, the extracted part of the injection distribution device 6 (Fig. 1) is raised to the surface using a fishing tool on a geophysical cable, wire or coiled tubing. In the seats 28, 29 (Fig. 2) install the upper 30 and lower 31 fittings. Then it is lowered on a geophysical cable, wire or coiled tubing installation or the extracted part of the injection distribution device 6 is dropped into the tubing string 2 before it is inserted into the body of the injection distribution device 6. Then, liquid is supplied into the cavity of the tubing string 2, which, passing through the converging channels 35, the lower central channel 36, and then the passage channel 37 of the diffuser 22, enters the lower layer 14. In the upper layer 15, the fluid enters through the upper central channel 30 (Fig. 3), diverging channels 34, and then the through channels nails 19 of the nipple 16. If it is necessary to pump only into the lower layer 14, the extracted part of the injection distribution device 6 is lifted to the surface using a fishing tool on a geophysical cable, wire or coiled tubing. A plug (not shown) is installed in the seat 28 (Fig. 3) of the upper sleeve 20, and the bottom fitting 31 is installed in the seat 29 of the diffuser 22. Next, they lower it onto the geophysical cable, wire or coiled tubing or dump the extracted part of the injection distribution device 6 into the tubing string 2 before it is inserted into the body of the injection distribution device 6. If it is necessary to pump only into the upper layer 15, the extracted part of the injection distribution device 6 is raised to the surface using a fishing tool for logging cable, a wire or coiled tubing installation. An upper fitting 30 is installed in the seat 28 of the upper sleeve 20, and a plug is installed in the seat 29 of the diffuser 22. Next, they lower it on a geophysical cable, wire or coiled tubing installation or discard the extractable part of the injection distribution device 6 into the tubing before it fits into the body of the injection distribution device 6. At the end of the liquid injection work, the layout is removed to the surface. To do this, by tensioning the tubing string 2 (Fig. 1), first the upper packer 7 and then the lower packer 3 are transferred to the transport position, then the assembly is lifted to the surface.

The claimed invention allows using an injection distribution device and at least one device for measuring the parameters of the injected fluid to perform controlled injection of fluid into the reservoirs, while making automated measurements of pressure, temperature, fluid flow and other process parameters into each of the reservoirs in real time time, to carry out processing and passage of geophysical instruments through an open passage channel to a device for measuring the parameters of the injected fluid.

Claims (4)

1. A method of controlled fluid injection into reservoirs with automated measurement of process parameters, including descent into a well on a string of tubing assembly of underground equipment consisting of a funnel, a lower packer, a disconnector, an injection distribution device, an upper packer, a disconnector, an extension cord installation of the lower and then upper packers, crimping, starting the well into operation, supplying fluid to the tubing cavity, measuring the main parameters of the fluid injection, when ex Using the actual costs from the set values, the extracted part of the injection distribution device is lifted and the upper and lower fittings are installed in the seats of the extracted part of the injection distribution device, the extracted part of the injection distribution device is lowered into the tubing before it is inserted into the housing part of the injection distribution device, and controlled injection is carried out liquids, at the end of work, lift the assembly to a surface, characterized in that they install the device for measuring the parameters of the injected fluid, an anchor is installed above the upper packer, a control cable is laid along the submersible downhole equipment from the device for measuring the parameters of the injected fluid to the monitoring station located at the wellhead, the fluid is supplied to the tubing cavity, the main parameters of the fluid injection are measured and other process parameters in one of the strata by the direct method of measurement, and in the other stratum by the indirect method: the main process parameters are determined in one m from the strata, on another stratum, the process parameters are determined by subtracting the measured flow rate from the device for measuring the parameters of the injected fluid from the total flow rate measured by the well flowmeter, if it is necessary to pump only the bottom part of the injection distribution device is lifted to the surface, the plug is inserted into the landing the place of the upper sleeve, and the lower fitting is installed in the seat of the diffuser, the extracted part of the devices is lowered or dumped the distribution of the injection into the tubing string before it fits into the body of the injection distribution device, if necessary, only the upper layer is lifted, the extractable part of the injection distribution device is raised to the surface, the upper fitting is installed in the seat of the upper sleeve, and the plug is lowered into or dump the extracted part of the injection distribution device into the tubing before it fits into the body of the injection distribution device. 2. The method according to p. 1, characterized in that the arrangement above the lower packer is equipped with a device for measuring the parameters of the injected fluid. 3. The method according to p. 1, characterized in that the anchor perform the mechanical or hydraulic principle of operation with grooves along the body. 4. The injection distribution device, which includes a housing part, consisting of interconnected nipples with several through channels, a housing and an adapter sleeve, an extractable part consisting of upward from the upper sleeve, lower sleeve and diffuser, while the extracted part is inserted into case part with the formation of a chamber, the upper and lower sealing units are installed on the lower sleeve, the first of which is fixed with a nut from the bottom, and the last is limited by a stop at the top, the landing gears are made in the upper sleeve and diffuser e places for the upper and lower fittings or plugs, moreover, the upper sleeve additionally has a seat for the plug, and the upper central channel is made in the lower sleeve, branching with the formation of several diverging channels associated with the camera and with through channels of the nipple, as well as several converging channels forming the lower Central channel, in communication with the passage channel of the diffuser, characterized in that on the device on the outer side surface there is a longitudinal groove in the form of a channel, and also the passage channel of the diffuser is made in the form of a diverging cone, passing into the cylinder.

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