RU2353440C1 - Universal chamber for introducing or receiving cleaning elements for pipeline cleaning - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention refers to oil and gas industry and can be implemented for introducing and receiving cleaning elements. The chamber consists of a case made in form of a pipe section creating a linking-up chamber designed to connect ends of the chamber to the cleaned pipeline, of two pipe-bends from the linking-up chamber arranged one above another and connected to the chamber; the pipe-bends present a chamber-capacity for cleaning elements, and of a branch. A disk valve is installed in the chamber-capacity and the branch; the disk valve consists of a seat and a piston with a rod; the seat of the valve is arranged in the said chamber-capacity in the zone of its entry to the linking-up chamber to disconnect the latter with the chamber-capacity; the piston with the rod is assembled in the branch and is designed to perform translational displacements till interaction with the seat of the chamber-capacity, while a free end of the rod is connected to the facility of its displacement. The linking-up chamber is equipped with a cleaning elements movement limiter. Also the chamber-capacity for cleaning elements is made in form of an elbow pipe-bend, angle of tilt of which relative to transverse axis of the linking-up chamber is approximately 30-80°, while the linking-up chamber is equipped from ends with flanges with stops facilitating connection to the pipeline and allowing regulation of space arrangement of the chamber-capacity and the branch along a circular trajectory around the lengthwise axis of the linking-up chamber.

EFFECT: invention facilitates increased efficiency and reduced labour intensiveness.

8 cl, 2 dwg

Description

The invention relates to the oil and gas industry, in particular, to the design of a universal chamber, which can be used both to start and receive in-line treatment elements, in particular bodies of revolution - balls, when cleaning the pipeline in order to remove asphalt-resin-paraffin deposits (AFS) from pipelines of an oil recovery system using treatment elements.

A number of start-up chambers and chambers for receiving treatment elements used in cleaning pipelines are known from the prior art (Oil production reference book edited by Sh.K. Gimatudinov. M .: Nedra, 1974, p. 605, 606, Fig. XIV. 64; Certificate of the Russian Federation for ПМ №5741; 6154; 18961; RF Patent №2129923 and others). The main disadvantage of these cameras is the lack of versatility, i.e. Each of them has its own design features that allow it to be used either only as a launch chamber, or only as a reception chamber. This leads to additional material costs in the implementation of cleaning technology. In addition, these chambers are suitable for use only for those pipelines that are quite high from the ground.

Only one universal chamber is known from the prior art for launching or receiving in-line cleaning elements during operation of pipelines, which is part of a device for cleaning a pipeline (RF Patent No. 2129923, class B08B 9/04, publ. 1999). The specified camera consists of an adapter, a housing and an end shutter, the hinged cover of which has a special design, while the length of the camera housing is 3.0-16.0 diameter of the adapter. This camera is selected as a prototype.

The main disadvantage of this known chamber is the impossibility of its operation without shutting off the fluid flow in the pipeline, which makes its use inefficient.

The closest to the proposed technical solution for the totality of features is a chamber for receiving treatment elements when cleaning the pipeline, known from the RF Patent No. 18961, cl. B08B 9/04, publ. 2001. The aforementioned known chamber is made in the form of a pipe, flanged connections connected to the pipe being cleaned, the accumulator of cleaning elements in the receiving chamber is made in the form of a cylinder with a sealed removable cover, placed perpendicularly to the pipe and communicated with it, and an additional pipe is made coaxially with the drive, hermetically blocked from the free end, inside of which the piston with the rod is placed with the possibility of translational movement, moreover, the piston seat is installed at the inlet to the drive, and in the piston no bypass valve, while in the nozzle of the reception chamber at the entrance to the drive installed limiter.

However, the specified well-known camera is not designed to run cleaning elements. The lack of versatility leads to additional material costs in the implementation of cleaning technology. In addition, this chamber is suitable for use only for those pipelines that are quite high from the ground.

The present invention solves the technical problem of increasing productivity, reducing the complexity of piping cleaning from ASPO and simplifying maintenance through the use of standardized chambers suitable for use both as a chamber for starting treatment elements and a chamber for receiving them while ensuring the possibility of using cleaning elements of both spherical and other shapes, as well as use on pipelines spatially placed at any distance yanii from the earth's surface or from a nearby equipment, while maintaining the possibility of launching and receiving cleaning elements run without receiving chambers and fluid flow in the pipeline covering.

The technical result is provided by a universal camera for starting or receiving cleaning elements when cleaning a pipeline, including a housing made in the form of a pipe section forming a docking chamber, which is designed to connect the camera at the ends to the pipe being cleaned, and two taps from the specified docking chamber placed each above the other with the possibility of communication with it and representing a chamber-container for cleaning elements and a pipe, while in the specified chamber-containers and pat the valve has a poppet valve consisting of a seat and a piston with a stem, a valve seat is located in the said chamber-container and installed in the zone of its entry into the docking chamber to disconnect the latter from the chamber-container, the piston with the rod is installed in the nozzle with the possibility of translational movement before interaction with the saddle of the chamber-container, and the free end of the rod is connected to the means of its movement, while the docking chamber is equipped with a limiter for the movement of the cleaning elements, new is that the chamber-container for the cleaning elements are made in the form of a knee-shaped outlet, the angle of inclination with respect to the transverse axis of the docking chamber is approximately 30-80 °, and the docking chamber from the ends is equipped with flanges with clamps, which make it possible to connect it to the pipeline with regulation of the spatial placement of the chamber-container and the pipe in a circular path around the longitudinal axis of the docking chamber.

The chamber-container and the pipe are equipped with end closures from the end remote from the docking chamber.

The free end of the rod is discharged through the end valve outside the nozzle.

The connection of the free end of the rod with the means of movement is made in the form of a helical gear with a helm.

The poppet valve piston is equipped with an annular seal corresponding to the shape of the seat.

The poppet valve piston is equipped with an overflow valve.

The chamber-tank is equipped with a pressure relief unit.

The movement limiter of the cleaning bodies of the docking chamber is made in the form of a lattice.

The achievement of the specified technical result is ensured by the following.

Due to the fact that the proposed camera for launching or receiving is made of interconnecting docking chamber, as well as a chamber-container and a nozzle (in practical design, the latter are located essentially coaxially one above the other in essentially mutually perpendicular planes), and also due to the fact that In the chamber chamber and in the nozzle, a poppet valve of a specified design is installed in a special way, during operation of which, during the translational movement of the piston to the saddle, it is possible at the required times disconnect the chamber-container from the docking chamber and thereby carry out work on loading the cleaning elements (or unloading them) into the chamber-tank without blocking the fluid flow in the pipeline being cleaned and at the same time ensure a decrease in labor intensity and increase productivity.

The implementation of the camera of the proposed design is unified, i.e. Suitable both for the purpose of starting the treatment elements and for receiving them, it simplifies the process flow diagram for connecting the entire chamber to the pipeline. In addition, this fact allows us to simplify the maintenance of these cameras in the process.

The implementation of the camera-capacity in the form of a knee-shaped bend with an inclination to the transverse axis under the docking chamber at an angle of 30-80 ° allows you to place the inventive camera in a pipeline located at any distance from the ground or from nearby equipment. This circumstance also makes it possible to simplify and facilitate the work of the operator, to ensure unimpeded supply and removal of treatment elements, and not only of a spherical shape.

The execution of the bypass valve nozzle in the piston provides a condition for equalizing the pressure in the pipeline being cleaned (docking chamber) and in the chamber chamber, thereby reducing the force on the rod movement means (helm with helical gear) when the poppet valve is opened.

The tightness of the poppet valve ensures the safe conduct of work both on loading the cleaning element into the chamber-container (in the case of the chamber for starting), and on removing the cleaning element from it (in the case of the reception chamber), as well as on cleaning the reception chamber from the AFS.

Providing a docking chamber with a limiter for the movement of the treatment elements installed at the boundary of the communication zone with the chamber-container and pipe and shifted towards the uncleaned pipeline allows the specified cleaning elements to move only on the cleaned section of the pipeline.

The essence of the invention is illustrated by drawings, where figure 1 shows the layout of the device for cleaning the pipeline, consisting of the proposed chamber for starting and receiving chamber of the cleaning elements; figure 2 and figure 3 presents the inventive camera for starting and the receiving chamber of the cleaning elements, respectively, indicating the possible positions for regulating the spatial placement of the chamber-tank and pipe in a circular path around the longitudinal axis of the docking chamber.

The device for cleaning the pipeline contains the proposed chamber 1 for starting the treatment elements and the receiving chamber 2, built into the cleaned pipe 3 in the reverse view (a camera that performs the function of the camera for starting is built into the cleaned pipe so that its chamber-container is oriented upwards, and the camera, which performs the function of the reception chamber, is built into the pipe being cleaned so that its chamber-container is oriented downward) and hydraulically connected through the specified pipe 3 to each other.

The chamber 1 for starting the cleaning elements 4, for example balls, is made in the form of a docking chamber 5, which is flanged 6 integrated into the cleaned pipe 3. Above the specified docking chamber 5 is placed and communicated with it chamber-container 7 in the form of an elbow-shaped outlet (the angle of inclination of this the knee-shaped outlet with respect to the transverse axis of the docking chamber is in the range of approximately 30-80 °, the optimum is 45 °; moreover, this angle of inclination is selected based on the design features of the pipeline and based on the distance location of it above ground level), at the end of the hermetically closed stopper 8 with nut 9 (act as an end shutter). A cylindrical pipe 10 is mounted coaxially with the chamber-container 7 under the docking chamber 5, hermetically closed by the end shutter 11. The docking chamber 5 is equipped with a limiter 12 for the movement of balls 4 (shifted towards the uncleaned pipeline), made, for example, in the form of a grid of rods. In the chamber-container 7 and in the pipe 10, a poppet valve is installed, consisting of a seat 13 located in the chamber-container 7, made in the form of an o-ring, and from a piston 14 placed in the pipe 10 with a running rod 15. The piston 14 is made with an outer ring seal corresponding to the shape of the seat 13, and has a bypass valve 16. To ensure the translational movement of the piston 14 in the nozzle 10, the rod 15 is connected with a means of moving it, for example, by means of a helical gear 17, made in the form of a screw-nut associated with the helm 18. The chamber-container 7 is equipped with a valve 19 to relieve pressure.

The design of the ball receiving chamber 2 of the balls 4 is similar to the launch chamber 1 and is made in the form of a docking chamber 20, which is flanged 21 integrated into the pipe 3 to be cleaned. Underneath the specified docking chamber 20, a container chamber 22 is placed and communicated with it in the form of an elbow outlet, at the end hermetically closed by a stopper 23 with a nut 24 (perform the role of the end shutter). Coaxially with the chamber-capacity 22 above the docking chamber 20, a pipe 25 is mounted, hermetically closed by the end shutter 26. The docking chamber 20 is equipped with a limiter 27 for the movement of balls 4 (shifted towards the uncleaned pipeline). In the chamber-container 22 and in the nozzle 25, a poppet valve is installed, consisting of a seat 28 located in the chamber-container 22, made in the form of an o-ring, and from a piston 29 located in the nozzle 25 with a running rod 30. The piston 29 is made with an outer ring seal corresponding to the shape of the seat 28, and has a bypass valve 31. To ensure the translational movement of the piston 29 in the nozzle 25, the rod 30 is connected through a helical gear 32, made in the form of a screw-nut, with the helm 33. The chamber-container 22 is equipped with a valve 34 for dumping pressure I am. At the entrance to the reception chamber 2, a mechanical sensor 35 with a signaling device in the form of a flag can be installed. The chamber-capacity 7 in the chamber 1 for starting accommodates one ball 4. The chamber-capacity 22 of the receiving chamber 2 also holds one ball 4, which is caused by the need to regularly clean it after the arrival of the ball 4.

The largest diameter of the ball 4 is made smaller than the diameter of the passage section of the seats 13 and 28 of the poppet valve.

Cleaning elements - balls 4 are made of porous polyurethane with a waterproof protective shell of various hardness. In addition, they may have a shape other than spherical.

The flanges 6 and 21 of the chambers have a series of fixing holes 36 (FIGS. 2 and 3), through which the docking chambers 5 and 20, respectively, can be connected to the pipeline 3 so that the chamber chambers 7 and 22 and, accordingly, the pipes 10 and 25 can be oriented in space in a different position along a circular path around the longitudinal axis of the docking chamber. For example, if flanges 6 and 21 had each 12 locking holes, then the docking chamber could be connected to the pipeline with a displacement along a circular path around its longitudinal axis each time by 30 ° (with a shift of one fixing hole 36). This allows you to spatially optimally place the claimed camera relative to the pipeline, depending on the technological needs and design features of the pipeline.

The inventive camera for starting and receiving, mounted in a device for cleaning the pipeline, operate as follows.

In the initial state, the piston 14 of the starting chamber 1 is in its lowest position, the cavity of the chamber-container 7 is in communication with the cavity of the pipe 3. In the receiving chamber 2, in the initial position, the sensor flag 35 is set perpendicular to the pipe 3. (The sensor 35 is preliminarily adjusted with the adjustment screw to the required actuation load to exclude actuation from the movement of viscous paraffin in the fluid flow). The piston 29 of this chamber 2 is withdrawn from the seat 28 and is in its highest position. The camera tank 22 is also in communication with the pipeline 3.

Before loading the ball 4 into the chamber-container 7, it is necessary to use the steering wheel 18 to move the piston 14 all the way into the seat 13, while the chamber-container 7 will be disconnected from the pipeline 3. With a crane 19, depressurize the chamber-container 7 to atmospheric pressure. Load the ball 4 into the chamber-container 7 through the hatch (plug 8 and nut 9) and use the steering wheel 18 to move the piston 14 to its lowest position, while the ball 4 moves under its own weight into the cavity of the docking chamber 5, in which it is picked up by the flow and moves along the pipeline 3 with a fluid flow rate, in contact with the walls and thereby removing the paraffin deposited on the walls, which, along with the liquid flow, moves along the pipeline 3. Ball 4, passing through the cleaned section of the pipeline 3, reaches the mechanical sensor 35, while m the sensor’s flag deviates from the vertical position and thereby signals the entry of the ball 4 into the receiving chamber 2 (supplying the receiving chamber with a sensor-signaling device, for example, a flag, or magnetic elements allows you to reliably establish the arrival of the cleaning element in the chamber-container. When these magnetic elements are installed in the camera in the cleaning element include permanent magnets). It is also possible to use other sensors to determine the arrival of the treatment element in the chamber-container.

Thanks to the limiter 27, the ball 4 stops at the entrance to the chamber-container 22. The movement of the ball 4 into the chamber-container 22 is carried out by moving the piston 29 during rotation of the helm 33. At the same time, the fluid flow in the pipeline 3 does not overlap. The said stops 12 and 27 in the launch chamber and in the reception chamber are mounted mirror-relative to each other with offset to opposite sides of each other (that is, the stops are displaced in each chamber closer to the area of the uncleaned pipeline), this eliminates uncontrolled “leaving” treatment elements outside the cleaned section of the pipeline.

To remove the ball 4 from the chamber-container 22, it is necessary that the piston 29 is seated in the seat 28, the bypass valve 31 is closed, in this case, the chamber-container 22 is cut off from the flow in the pipeline 3. The valve 34 is opened and the pressure is released from the chamber-container 22 to atmospheric pressure. After that, the hatch is opened (it may be nut 24 and plug 23) and the ball 4 is taken out and the chamber-container 22 is cleaned of sediments and paraffin that fell with the ball 4. After that, the chamber-container 22 is again hermetically closed, the valve 34 is closed, the valve 34 is moved the piston 29 from the seat 28 to its highest position, and the flag of the mechanical indicator 35 is set vertically. Reception chamber 2 is prepared for receiving the next ball 4.

To clean the pipeline from ASPO at the initial stage of cleaning, it is preferable to run balls 4 of material with a lower hardness in the pipeline 3 first to ensure their better deformation and passage through a more contaminated pipeline.

If the ball 4 gets stuck in the pipeline 3, a magnet integrated inside the ball will help to find its location.

Thus, the proposed chamber for starting or receiving treatment elements allows the pipeline to be cleaned without stopping the fluid flow in the pipeline, has high efficiency and operational reliability, reduces energy and labor costs, and eliminates the most manual labor for stopping the operation of the pipeline. Also, there is no need for a large number of valves, it is conveniently included in the technological chain of the oil collection system. The camera is simple to manufacture, is unified. Thanks to its design features, it provides the possibility of use on pipelines running low above the ground. Due to the convenience of access to the camera-capacity facilitates the work of operators and increases productivity.

Claims (8)

1. A universal camera for starting or receiving cleaning elements when cleaning a pipeline, including a housing made in the form of a pipe section forming a docking chamber, which is designed to connect the camera at the ends to the pipe being cleaned, and two taps from the specified docking chamber placed one above the other with the possibility of communication with it and representing a chamber-tank for cleaning elements, and a nozzle, while in the specified chamber-tank and nozzle a poppet valve is installed, consisting of a piston with a rod, a valve seat is placed in the said chamber-container and installed in the zone of its entry into the docking chamber to disconnect the latter from the chamber-container, the piston with the rod is installed in the nozzle with the possibility of translational movement before interacting with the chamber-container saddle, and the free end of the rod is connected to the means of its movement, while the docking chamber is equipped with a movement limiter for the treatment elements, characterized in that the chamber-container for the treatment elements is made in the form of a knee-shaped about the outlet, the angle of inclination with respect to the transverse axis of the docking chamber is approximately 30-80 °, and the docking chamber from the ends is equipped with flanges with clamps, providing the ability to connect it to the pipeline with the regulation of the spatial placement of the chamber-container and pipe in a circular path around longitudinal axis of the docking chamber. 2. The camera according to claim 1, characterized in that the chamber-container and the nozzle are equipped with end closures from the end remote from the docking chamber. 3. The camera according to claim 1, characterized in that the free end of the rod is discharged through the end valve outside the pipe. 4. The camera according to claim 1 or 3, characterized in that the connection of the free end of the rod with the means of movement is made in the form of a helical gear with the helm. 5. The chamber according to claim 1, characterized in that the piston of the poppet valve is equipped with an annular seal corresponding in shape to the seat. 6. The chamber according to claim 1 or 5, characterized in that the piston of the poppet valve is equipped with an overflow valve. 7. The chamber according to claim 1, characterized in that the chamber-container is equipped with a pressure relief unit. 8. The camera according to claim 1, characterized in that the limiter of the movement of the cleaning bodies of the docking chamber is made in the form of a lattice.

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