RU73507U1 - LIQUID FLOW REGULATOR - Google Patents

Abstract

The fluid flow regulator contains a choke and a through half-housing, interconnected by nipples of shut-off valves. Flanges are attached to the choke and bore half-shells using studs and nuts. The half-case fitting is equipped with ceramic fittings and disk filters. Each nozzle and filter are installed in a cylindrical sample, which communicates through an opening on the nozzle half-housing with the cavity of the stopcock. In order to increase the coefficient of use of the fluid flow controller, each hole in the choke half-housing is made over the entire thickness of the choke half-housing. A threaded selection is made perpendicular to the axis of each hole and the axis of the choke half-housing from the side wall of this half-housing. From the bottom of the threaded set, a conical set is made with a tapered surface tapering to the axis of the choke half-housing. A fitting holder is installed in each conical selection. It is made in the form of a truncated cone having, on a large base, a coaxially located rod with a threaded protrusion at the free end. A groove is made at the free end and along the diameter of the threaded protrusion. A screw is screwed into each threaded selection of the choke half-housing. It has at its free end, for example, two holes of the same diameter located along the diameter of the end face, and a through hole. It is aligned with the screw. The height of the screw is selected less than the length of the rod, and the diameter of the through hole is selected greater than the diameter of the rod. The screw is fixed to the rod with a nut, screwed onto the threaded protrusion of the truncated cone. A threaded plug having a cylindrical selection made from its inner end is wrapped in each threaded selection of the choke half-housing. The diameter of the cylindrical sample tube is selected larger than the outer diameter of the nut. On each fitting, parallel to the groove of the threaded protrusion and opposite the hole adjacent to the shut-off valve, a cylindrical selection is made. It is equipped with a ceramic fitting and a disk filter, which is fixed from the exit from the cylindrical sample by an elastic plate. These plates are in contact with the middle part with

surface of the filters, and two ends with the surface of the cylindrical samples. The length of the elastic plate is selected slightly larger than the diameter of the cylindrical sample of the fitting. A through hole is made on the nozzle holder from the bottom of the cylindrical sample coaxially to this sample. The diameter of each through hole, for example, on the through half-shell, is selected to be larger than the outer diameter of the nipple of the stopcock. Cylindrical and threaded seams are made coaxially to each through-hole of the bore-through half-housing and from the side of the nipple from the end of the bore-through half-body. A seal of the nipple is installed in each cylindrical sample, and the threaded part of the front box is wrapped in each threaded sample. It is made in the form of a sleeve with an external thread. An annular protrusion of an additional filter is installed in each cylindrical hole of the through-case half-case. It is made in the form of a cap with an annular protrusion on the open end and through holes on the side wall and on the bottom. The nipple of the stopcock is installed in the cavity of each cap. The ends of, for example, four studs located on the union half-housing are rigidly connected by rods to the opposite ends of the studs located on the through-half-housing. The diameter of each rod is selected slightly less than the diameter of the protrusion of the thread of the stud nut.

Description

The invention 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 ..0-30x210, passport RRZH 00.00.000PS, manufacturer LLC "LOZNA", 423250, Republic of Tatarstan, Leninogorsk, Tchaikovsky St., d-40) containing a fitting and a through half-housing, interconnected by nipples of shut-off valves, moreover, flanges are attached to the choke and bore half-bodies with flanges with nuts, and the choke half-casing is equipped with ceramic fittings and disk filters, each choke and filter installed in a cylindrical sampling communicating through an opening on the piece a half-shell with a cavity of a stopcock. A disadvantage of the known fluid flow regulator is its low utilization rate. To replace a ceramic fitting or several ceramic fittings, as well as to replace a stopcock, the fluid flow regulator is completely removed from the pipeline. This consumes a significant portion of the operating time of the fluid flow controller and reduces the utilization rate.

The aim of the invention is to increase the utilization of the fluid flow controller. This goal is achieved by the fact that in the fluid flow regulator containing the choke and bore half-shells, interconnected by nipples of shut-off valves, flanges are attached to the choke and bore half-shells, moreover, the choke half-shell is equipped with ceramic fittings and disk filters, each the nozzle and filter are installed in a cylindrical sample communicating through an opening on the choke half-housing with the cavity of the shut-off valve, with each hole on the choke half-housing made over the entire thickness

a threaded fitting, moreover, perpendicular to the axis of each hole and the axis of the fitting half-housing, a threaded selection is made from the side wall of this half-housing, and a conical selection is made from the bottom of the threaded selection with a tapered surface tapering to the axis of the fitting half-housing, a fitting made in the form of a truncated a cone having, on a large base, a coaxially spaced rod with a threaded protrusion on the free end, and on the free side, and a cut in diameter A groove is made in the groove, and a screw is screwed into each threaded selection of the choke half-housing, having, for example, two identical diameters and openings located along the diameter of the end face, and a through hole located coaxially with the screw, the screw height being selected less than the rod length and the diameter the through hole is selected larger than the diameter of the rod, and the screw is fixed on the rod with a nut wrapped on a threaded protrusion of a truncated cone, and each thread is threaded into a fitting half-case a cork having a cylindrical selection made from its inner end, the diameter of the cylindrical selection being larger than the outer diameter of the nut, and on each fitting, parallel to the groove of the threaded protrusion and opposite the opening adjacent to the stopcock, a cylindrical selection is provided with a ceramic fitting and a disk filter moreover, a through hole is made on the nozzle holder from the bottom of the cylindrical sample coaxially to this sample, and the diameter of each through hole, for example, on one half-case is selected larger than the outer diameter of the nipple of the stopcock, moreover, coaxial to the through-hole of the through-and-through half-body and from the side of the nipple from the end of the through-and-through half are cylindrical and closer to the end faces of the threaded seals, with a seal of the nipple installed in each cylindrical selection, and a threaded sealed in each threaded set part of the packing follower, made in the form of a sleeve with an external thread, the filter being fixed from the exit from the cylindrical sample by an elastic plate in contact with edney part of the filter surface and two ends - with a cylindrical surface of a sample, wherein the elastic plate is selected length slightly greater than the diameter of the cylindrical sample

a nipple holder, moreover, an annular protrusion of an additional filter is installed in each cylindrical opening of the through-half-housing, made in the form of a cap with an annular protrusion on the open end and through holes on the side wall and on the bottom, and a nipple of a stopcock is installed in the cavity of each cap, and the ends, for example, four studs located on the union half-housing are rigidly connected with rods to opposite ends of the studs located on the through-shell half-case, the diameter of each rod ny slightly smaller than the diameter of the protrusion of the thread of the stud nut.

Figure 1 shows a General view of the fluid flow regulator (hereinafter - the regulator) in the context; figure 2 is a view of I figure 1; figure 3 is a view II of figure 1

The controller contains a fitting 1 (Fig. 1) and a through passage 2 half-bodies, interconnected by nipples 3 of four shut-off valves (hereinafter - the crane) 4. Flanges 7 are attached to the free ends of these half-cases using studs 5 and nuts 6. On the connection 1 and through-passage Two through holes 8 are made in the half-shell 2, each of which communicates with the cavity of a separate nipple 3 of the crane 4. A threaded set 9 is made perpendicular to the axis of the upper hole 8 and the axis of the choke half-housing 1 and opposite to these axes manner opposite to the lower openings 8 and opposite the threaded sample 9 is the same threaded sample 9. Also right threaded sample 9 with choke side wall half shell 1 opposite to the other two holes 8 are threaded sample 9 (Fig. not shown). From the bottom of each threaded seam 9, a conical seam 10 is made with a tapered surface 11 tapering to the axis of the choke half-housing 1. A choke 12 is installed in each conical seam 10, made in the form of a truncated cone 13 (Fig. 2). The latter has on a large base coaxially located rod 14 with a threaded protrusion 15 at the free end. A groove 16 is made on the free end and along the diameter of the threaded protrusion 15. A screw 17 is screwed into each threaded seam 9 of the nipple half-housing 1. These screws have two identical diameters on the free end located along the diameter of the end face 18 and the through hole 19 located coaxially to the screw 17. The height of each screw 17 is selected slightly less than the length of the rod 14, and

the diameter of the through hole 19 is selected to be larger than the diameter of the rod 14. The screws 17 are fixed on the rods 14 with two nuts 20, screwed onto the threaded protrusions 15 of the truncated cones 13. A washer 21 is installed between the rod 14 and the nuts 20 on the threaded protrusion 15. 1 is screwed with a gasket 22 a threaded plug (hereinafter referred to as a plug) 23 having a cylindrical sample 24. It is made from the inner end of the plug 23 and its diameter is selected larger than the outer diameter of the nut 20. There are 13 pieces on each truncated cone holder 12 parallel to the groove 16 of the threaded protrusion 15 and opposite the right side of the hole 8, adjacent to the valve 4, a cylindrical selection 25 is made. It is equipped with a ceramic fitting 26, which has an axial through hole (not shown in Fig.), and a disk filter 27. The latter fixed from axial movement by an elastic plate 28, which in the middle part is in contact with the right surface of the filter 27, and two with the surface of the cylindrical sample 25. The length of the elastic plate 28 is selected slightly larger than the diameter of the cylindrical sample 25 w end holder 12. On the nozzle holder 12 from the bottom of the cylindrical sample 25, coaxial to this sample, a through hole 29 is made. The diameter of each through hole 8 on the bushing half housing 2 is selected larger than the outer diameter of the nipple 3 of the crane 4. Coaxial to each through bore 8 of the bushing half housing 2 and from the side the nipple 3 from the end 30 is made cylindrical 31 (figure 3) and closer to the end 30 of the threaded 32 sample. An annular protrusion 33 (Fig. 3) of an additional filter 34, made in the form of a cap with an annular protrusion 33 at the open end and through holes 35 on the side wall 36 and on the conical bottom (position not given), is installed in each cylindrical opening 31 of the through passage half-housing 2; . The nipple 3 of the stopcock 4 is installed in the cavity of each cap, and the seal 37 of the nipple 3 is installed in each cylindrical sampling 31. The threaded part of the packing follower 38, made in the form of a sleeve with an external thread, is wrapped in each threaded sample 32. The right ends of, for example, four (a total of 8 hairpins) studs 5 located on the union half-housing 1 are rigidly connected using rods 39 to the opposite left ends of the studs 5 located on the passage floor of the housing 2. Diameter

each rod 39 is slightly smaller than the diameter of the protrusion of the thread of the nut 6 of the stud 5.

The fluid flow controller operates as follows. Suppose that all the taps are open behind the handles 40. A liquid, for example, water, passes under overpressure through the openings 35 of additional filters (hereinafter referred to as the filter) 34. At the same time, mechanical impurities (welding slag, stones and other solid impurities) are delayed by the bottom and a wall 36 of filters 34. Next, water enters the cavities of the right nipples 3, into the taps 4, the left nipples 3 and the holes 8 of the nipple half-housing 1. From the holes 8, the water enters the right cavities of the cylindrical samples 25 of the nipples 12. From there, the water passes through the openings of the filters 27 , inversion Ia ceramic nozzles 26, holes 29 and through holes shtutseroderzhateley 8 enters the cavity of the left flange 7. When moving the water through the hole 26 of ceramic nozzles, it ispytavala flow resistance and hence reduced water consumption. Filter 27 retain mechanical impurities (quartz sand, rust, slag, stones) and prevent the ingress of these impurities into the holes of the ceramic fittings 26. During operation of the regulator, the holes of the ceramic fittings 26 wear out and their diameters increase. Therefore, such ceramic fittings 26 are replaced with a new one. To do this, first close all the shutoff valves 4 by the handles 40 to reduce the water pressure in the cavities of the openings 8 of the nipple half-housing 1. Next, unscrew the plugs 23 from the threaded samples 9 of the nipple half-housing 1. Then, by installing the cylindrical protrusions of the tubular wrench in the holes 18, unscrew each screw 17 . In this case, the screw 17, acting with its outer end surface on the washer 21 and nuts 20, pulls the nipple holder 12 from the conical selection 10 and the shaft 14 from the conical selection 10. First, the elastic plate 28 is removed from it, and then the filter 27 and ke an amic fitting 26. On each removed fitting 12 instead of worn ceramic fittings 26, a new ceramic fitting 26 is installed. Next, they are installed in the cylindrical samples 25 of the filter 27 and locked with elastic plates 28. Each assembled fitting 12 is installed in its threaded set 9, directing the open part of the cylindrical sample 25 in the direction of the passage of the half-housing 2. Then, holding the screw holder 12 in

In this position, screw 17 is screwed into the threaded set 9 with a pipe wrench. In this case, the nozzle holder 12 enters the conical set 10. Then, with a screwdriver, the groove 16 is installed parallel to the axis of the choke half housing 1 and the screw 17 is screwed to a stop. In this case, the truncated cone 13 (fitting 12) is mounted in a conical sample 10 with a filter 27 opposite the nipple 3 of the crane 4, and the hole 29 is located opposite the hole 8 (as shown in figure 2). After installing each fitting 12 in the fitting half-housing 1 in the aforementioned manner, plugs 23 are screwed in after installing gasket 22 on them. Then, taps 4 are opened and the fluid flow regulator is started. To replace the failed valve 4, release the pressure in the cavities of the right and left flanges 7. Then unscrew the journal 38 to loosen the seal 37 on the right nipple 3 of the failed valve 4. Then, disconnect the right nipple 3 of the failed valve 4 by unscrewing the union nut ( in Fig. not shown) of this crane, and the nipple 3 is moved to the right. The right end of the nipple 3 is located to the right in the cavity of the filter 34. Also, a gap is formed between the nipple 3 and the failed valve 4. Next, by unscrewing the left union nut, disconnect the faulty valve 4 from the left nipple 3. Instead of this valve 4, the left locking nipple 4 is connected to the left nipple 3 with a union nut 4. The right nipple 3 is moved to it from right to left, which is connected (by tightening the union nut onto the valve connection ) with a working valve installed 4. After that, tighten the packing follower 38 to press the seal in order to ensure the tightness of the connection of the right nipple 3 with the through passage half-body 2. This embodiment of the regulator allows replacement 4 eispravnogo crane without removing other cranes and without moving devices Lug flange half shell 7 of the choke 1. Thus costs are reduced repair controller. When replacing cranes 4, as well as during operation of the regulator, the rods 39 provide a rigid connection of the choke and bore half-bodies to each other. This prevents the bending of the valve nipples and the breakdown of the regulator due to the appearance of cracks in the junction of the nipples with the fitting half-housing.

In the proposed fluid flow regulator, the replacement of the ceramic fitting, in contrast to the prototype, is carried out by removing the fitting by unscrewing the plug and screw 17. This takes much less time than dismantling the regulator itself, which is done in the prototype. Therefore, the proposed increases the utilization rate.

Claims (4)

1. A fluid flow regulator comprising a choke and bore half-housing, interconnected by nipples of shut-off valves, moreover, flanges are attached to the choke and bore half-housing with flanges and nuts, and the choke half-body is equipped with ceramic fittings and disk filters, each choke and filter installed in a cylindrical sample communicating through an opening on the choke half-body with a cavity of the stopcock, characterized in that each hole on the choke half-body is made throughout the entire a threaded half-housing, moreover, perpendicular to the axis of each hole and the axis of the choked half-housing, a threaded selection is made from the side wall of this half-housing, and a conical selection is made from the bottom of the threaded selection with a tapered surface tapering to the axis of the half-housing, and a fitting holder is made in each a truncated cone having, on a large base, a coaxially spaced rod with a threaded protrusion at the free end, and at the free end and in diameter a groove is made of the threaded protrusion, with a screw having, at the free end, for example, two identical diameters and openings located along the diameter of the end face, and a through hole located coaxially to the screw, the screw height being selected less than the shaft length and the diameter the through hole is selected larger than the diameter of the rod, and the screw is fixed on the rod with a nut wrapped on a threaded protrusion of a truncated cone, and a cut is wrapped in each threaded selection of the choke half-housing a filler plug having a cylindrical selection made from its inner end, the diameter of the cylindrical selection being larger than the outer diameter of the nut, and on each fitting, parallel to the groove of the threaded protrusion and opposite the opening adjacent to the shut-off valve, a cylindrical selection is provided with a ceramic fitting and a disk filter moreover, on the fitting from the bottom of the cylindrical sample coaxial to this sample, a through hole is made, the diameter of each through hole, for example, more than the outer diameter of the stopcock nipple is selected for the passage half-case, moreover, coaxial and threaded seams are made coaxially to each through-hole of the passage half-body and from the end of the passage half-body, moreover, the seal of the nipple is installed in each cylindrical selection and the threaded set is screwed part of the packing follower, made in the form of a sleeve with an external thread. 2. The device according to claim 1, characterized in that the filter is fixed from the exit from the cylindrical sample by an elastic plate in contact with the middle part of the filter surface and two ends with the surface of the cylindrical sample, the length of the elastic plate being selected slightly larger than the diameter of the cylindrical sample of the nozzle holder. 3. The device according to claim 1, characterized in that an annular protrusion of an additional filter is installed in each cylindrical hole of the through-case half-shell, made in the form of a cap with an annular protrusion at the open end and through holes on the side wall and at the bottom, with each cavity installed nipple stopcock. 4. The device according to claim 1, characterized in that the ends of, for example, four studs located on the union half-housing, are rigidly connected with rods to opposite ends of the studs located on the through-shell half-case, the diameter of each rod being selected slightly less than the diameter of the nut thread protrusion hairpins.