RU80971U1 - LIQUID FLOW REGULATOR - Google Patents

Abstract

The fluid flow regulator contains a choke and a through half-housing, interconnected by nipples of a stopcock. These half-shells contain flanges attached to their free ends. On the choke half-case there are ceramic fittings, equipped with stoppers and seals, and located in cylindrical samples. In order to reduce the cost of the fluid flow regulator and increase the convenience during its maintenance, both flanges are made with a cylindrical selection having a bottom. At the bottom of each flange, through cylindrical samples are made, located opposite the nipple of the stopcock and coaxially with the nipple of the stopcock. In each flange, the surface of the outer bottom wall is in the plane of the end face of the flange. A sealing gasket made in the form of a disk is installed at the bottom of the cylindrical sample. The filter is made with cylindrical samples, each of which is opposite the ceramic fitting. In each cylindrical sample, between the ends of the filter and the ceramic fitting opposite each other, a hollow cylinder is installed. It is made with through radial holes located opposite the side wall of the cylindrical filter sample. In another embodiment, the fluid flow regulator at the bottom of both flanges is aligned with a cylindrical through sampling.

Description

The utility model relates to devices designed to reduce the flow of fluid, for example, water injected into the well to maintain reservoir oil pressure.

Known fluid flow regulator (type RRZH .. 0-30 × 210, passport RRZH 00.00.000PS, manufacturing plant LLC "LOZNA", 423250, Republic of Tatarstan, Leninogorsk, Tchaikovsky St., 40), containing a fitting and half-bodies through passage, interconnected by nipples of a stopcock, and containing flanges attached to their free ends, moreover, on the choke half-case there are ceramic fittings equipped with stoppers and seals, and located in cylindrical samples. In the known fluid flow regulator, both flanges have a through cylindrical sample, the diameter of which is selected equal to the diameter of the bore connected to the pipe flanges. Due to the presence of such a cylindrical sample on the flanges, these flanges, as well as the fitting and bore half-shells, have significant external diameters. This leads to an increase in the linear dimensions and mass of the fluid flow regulator and to an increase in its prime cost. Stoppers and seals of ceramic fittings are located in ring samples. Performing these samples on the walls of the cylindrical samples also increases the cost of the fluid flow controller.

The purpose of the utility model is to reduce the cost of the fluid flow regulator. This goal is achieved by the fact that in the fluid flow regulator containing the choke and bore half-shells, interconnected by nipples of a stopcock, and containing flanges attached to their free ends, and on the choke half-body there are ceramic fittings equipped with stoppers and seals, and located in cylindrical samples, both flanges are made with a cylindrical sample having a bottom, and through the bottom of each flange are made through cylindrical samples, and

each cylindrical filter sample is located opposite the nipple of the stopcock and coaxially with the nipple of the stopcock, with the surface of the outer wall of the bottom in each flange being in the plane of the end face of the flange, with a gasket made in the form of a disk installed on the bottom of the cylindrical sample, and the filter is made with cylindrical samples, moreover, the cylindrical sample is opposite the ceramic fitting, and in each cylindrical sample, between the filter ends opposite the ceramic ends and the ceramic of the nipple, a hollow cylinder is installed, made with through radial holes located opposite the side wall of the filter cylindrical sample, and a through cylinder sample is made coaxially to the flange at the bottom of both flanges.

Figure 1 shows a General view of the fluid flow regulator in the context; figure 2 is a view of I figure 1. Figure 3 - flange in another embodiment of the device.

The fluid flow controller contains a fitting 1 and a passage 2 half-bodies connected by nipples 3 of a shut-off valve 4. These half-bodies contain flanges 5 attached to their free ends through ring gaskets 6 and with pins 7 and nuts 8. Both flanges 5 are made with a cylindrical a sample 9 having a bottom 10. At the bottom 10 of each flange 5, through cylindrical samples 11 are made, located opposite the nipple 3 of the stopcock 4 and coaxially with the nipple of this tap. In each flange 5, the surface of the outer wall of the bottom 10 is in the plane of the end face 12 of the flange 5. The filter 13 (Fig.2), made with through cylindrical samples 14, are installed in the cylindrical samples 15 of the choke half housing 1. Also, the blind cylindrical samples 16 are made on the filters 13 located opposite the ceramic fitting 17. Each ceramic fitting 17 is located in a cylindrical sample 18. From the bottom of the cylindrical sample 18, a coaxial cylindrical sample 19 is made. At the bottom of the cylindrical sample 18 is installed sealing rokladka 20, made in the form of a disk. The filter 13 is kept from axial movement by a retaining ring 21 installed in the annular groove of the cylindrical sample 15. In the cylindrical sample 18, between the ends opposite to each other

a filter 13 and a ceramic fitting 17, a hollow cylinder 22 is installed. It serves to prevent axial movement of the ceramic fitting 17 and is made with through radial holes 23 located opposite the side wall of the cylindrical sample 14 of the filter 13. On the through half-housing 2 opposite each nipple 3 are made cylindrical samples 24. In another embodiment, the device at the bottom of both flanges 5 is aligned with the flange 5 through a cylindrical sample 25 (figure 3).

The fluid flow controller operates as follows. Let's say one stopcock 4 is open, and the rest of the taps are closed. A liquid, for example, water, passing under overpressure through a cylindrical sample 9 of the left (in FIG. 1) flange 5 and a cylindrical sample 11 enters the cylindrical sample 15 of the choke half housing 1. From this sample 15, one part of the water through the through holes 14 of the filter 13 flows into the cavity 26 of the hollow cylinder 22. Another part of the water with a blind cylindrical sample 16 of the filter 13 passes through the through radial cylindrical samples 23 of the hollow cylinder 22 and enters the cavity 25 of this cylinder. From the cavity 26 of the hollow cylinder 22, water passes through the channel 27 of the ceramic fitting 17, the cylindrical sample 19, the channel 28 of the nipple 3, the shut-off valve 4, the cylindrical sample 24 of the passage half-body 2. Then the water enters the cylindrical sample 11 of the right flange 5, and then into the cavity 9 of this flange. From there, water enters the pipeline. Passing through the channel 27 of the ceramic fitting 17, due to the small passage section of this channel, water consumption is reduced. In another embodiment, water after a cylindrical sample 9 of the left flange 5 enters the cylindrical sample 25 of this flange. Then, the water passes through the fluid flow regulator as noted above, and after passing through the cylindrical sample 24 of the passage half-body 2, it enters the cylindrical sample 25 of the right flange 5. During operation of the fluid flow regulator, the channel 27 of the ceramic fitting 17 wears out and the diameter of this hole increases. Therefore, such a ceramic fitting 17 is replaced with a new one. To do this, first reduce to atmospheric pressure in the fluid flow regulator. Then unscrew the nuts 8 from the studs 7 on the union half-housing 1, as well as the left

union nuts of shut-off valves 4. Next, remove the studs 7 from the union half-housing 1 and, moving the left flange 5 to the left, remove the union half-housing 1 together with the left nipples 3 from the fluid flow regulator. First, the retaining ring 21 is removed from the union half-case 1, filter 13, a hollow cylinder 22, and then a worn ceramic fitting 17. Together, a new ceramic fitting 17 is installed. Next, a filter 13 is installed and a fluid flow regulator is assembled in the reverse order of disassembly.

In the proposed fluid flow regulator, designed for connection, for example, to pipes with a DN of 100 mm with a working pressure of 21 MPa, flanges and half-shells with an outer diameter of 245 mm and studs with nuts with M24 thread are used, and in the prototype flanges and half-shells are 292 mm and studs and nuts with M30 thread. Therefore, the proposed fluid flow control is more compact and in its manufacture requires less materials (steel forgings) and less manufacturing costs. Therefore, its cost is reduced in comparison with the prototype. Unlike the prototype, in the proposed fluid flow regulator, the cylindrical samples, where the ceramic fittings are installed, are made without ring samples. Because of this, the cost of the regulator is also reduced. Hollow cylinders are used in the proposed fluid flow regulator to fix ceramic fittings. Removing and installing them is done by hand without tools and quickly compared to the prototype. This increases the convenience when servicing the proposed fluid flow controller.

Claims (6)

1. A fluid flow regulator comprising a choke and bore half-shells interconnected by nipples of a stopcock and containing flanges attached to their free ends, moreover, on the choke half-body there are ceramic fittings equipped with stoppers and seals and located in cylindrical samples, characterized in so that both flanges are made with a cylindrical sample having a bottom, and at the bottom of each flange, through cylindrical samples are made, and each cylindrical sample is located opposite in the nipple of the stopcock and coaxially with the nipple of the stopcock. 2. The device according to claim 1, characterized in that in each flange the surface of the outer wall of the bottom is in the plane of the end face of the flange. 3. The device according to claim 1, characterized in that a sealing gasket made in the form of a disk is installed at the bottom of the cylindrical sample. 4. The device according to claim 1, characterized in that the filters are made with cylindrical samples, and the cylindrical filter sample is opposite the ceramic fitting. 5. The device according to claim 1, characterized in that in each cylindrical sample between the opposite ends of the filter and the ceramic fitting there is a hollow cylinder made with through radial holes located opposite the side wall of the cylindrical filter sample. 6. The device according to claim 1, characterized in that at the bottom of both flanges, a through cylindrical selection is made coaxially to the flange.