RU2330937C1 - System for prevention of sediments formation in pipeline including pipelines on comlex lay of land (versions) - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention refers to oil and gas industry, particularly to devices for prevention of sediments formation in main pipelines and exhaust lines. The system includes a pipeline, and a hydraulically connected thereto reagent injection branch unit containing a case rigidly fixed to the pipeline; at that a reagent module is placed inside the case. An aperture with a plug is made in the case of the reagent injection unit; the reagent module charging and control for hard reagent presence in the case is performed through the said aperture. The reagent module is designed removable, hydraulically permeable and consisting of at least one autonomous hydraulically permeable chamber serving for horizontal or vertical reagent charging; the module is fixed directly in the reagent injection unit case or on aperture plug of the said case. According to the second variant the reagent injection unit case is made as a bypass line. As to the third variant the reagent injection unit case is located inside the pipeline and is fixed on the plug of the aperture made on the pipeline for the injection unit placement.

EFFECT: upgraded reliability, efficiency and functionality of the system.

29 cl, 3 dwg, 1 tbl

Description

The invention relates to the oil industry, in particular to devices for preventing the formation of deposits in the pipeline, and can be used both in trunk pipelines and in flow lines in oil fields, i.e. where proportional introduction of a solid inhibitor reagent into the transported stream is required.

The principle of operation of the proposed inventions is to ensure the prevention of deposits, for example, asphalt-resin-paraffin, salt, hydrated, etc., in pipelines by washing off the product of the solid inhibitor-inhibitor with the dissolution of the latter. Considering that solid reagent-inhibitors appeared relatively recently, their prevention of deposits in pipeline transport requires a certain amount of work (prevention of deposits in a pipeline by liquid reagents is carried out by a number of well-known dosing devices developed and used in fields during transportation and oil treatment).

In addition, this problem of preventing deposits in pipelines is especially relevant in areas with difficult terrain (ravines, elevations, obstacles, etc.). In the pipeline that runs in these areas, due to the departure from horizontal laying, the speed of the transported product changes, as a result of which its equilibrium state changes and there is an increased formation of deposits on the walls of the pipeline. This leads to a change in the bore of the pipeline. That is why the solution to the problem of preventing such deposits is a very important problem in pipeline transport.

A known system for odorizing gas (RF application No. 95110413, class B01F 3/02 of 1995) (selected as an analogue, because it has common features according to the technical approach with the proposed system), containing a diaphragm installed in the pipeline, odorizing device - reagent module, temperature controller, heater and pressure and temperature sensors.

A known system for preventing the formation of deposits in the pipeline is a dispenser for liquid reagents (RF Patent No. 22979795, class G01F 11/00, 2003), containing a container with a liquid reagent connected by two pipes to the pipeline, while the pipeline is made in an arc circles. One nozzle designed to supply replacement fluid from the pipeline is attached to the outside of the arc. Another nozzle attached to the bottom of the container and used to deliver the reagent to the pipeline is connected to the inside of the arc.

The disadvantage of this dispenser is that for efficient operation it must be installed on a section of a pipeline made along a circular arc in a horizontal plane, which causes technological difficulties and increased material costs. In addition, it cannot be used on a pipeline laid in areas with complex terrain.

In addition, with unstable pressure in the pipeline, the flow of liquid reagent into the pipeline will also be unstable, which reduces the efficiency of the dispenser.

Closest in technical essence to the claimed variants of technical solutions is a system for the metered supply of a chemical reagent (RF Patent No. 2254448, CL ЕВВ 43/00, 2003), consisting of a pipeline and a branch reagent input unit hydraulically connected to it containing a housing rigidly connected to the pipeline with a reagent module located inside it in the form of an elastic chamber filled with a liquid reagent-inhibitor.

The work of the known system is as follows. The transported products from the pipeline enter the case of the reagent input unit, compressing the elastic chamber of the reagent module and squeezing the liquid reagent from it into the pipeline.

The disadvantage of this known system is that at insufficient pressure a small (insufficient) volume of liquid reagent is squeezed out in the pipeline, which does not provide guaranteed prevention of deposits. In addition, with possible pressure surges in the pipeline, the operation of the known system will be unstable.

At the same time, the cycle of the known system from filling the chamber with a liquid reagent to its full use will be short, which is a negative point in the technological plan.

A single technical result achieved by the proposed variants of the invention is to increase the reliability, efficiency and functionality of the system due to the possibility of using solid inhibitor-reagent to prevent deposits, due to the uniformity of its washing off by the transported medium with the provision of a proportional and technologically required flow rate and by increasing the operating period without replacing the reagent in the reagent module.

The specified technical result is provided according to the first two options of the proposed system to prevent the formation of deposits in the pipeline, including in areas with complex terrain, consisting of a pipeline and from a hydraulically connected branch of the reagent inlet containing a housing rigidly connected to the pipeline with an inside reagent module, new in the first embodiment, is that in the housing of the input unit there is a window with a plug for loading the reagent module and control the presence of a solid reagent in it during operation, while the reagent module is made removable, hydraulically permeable and consisting of at least one autonomous hydraulically permeable chamber with horizontal or vertical loading of solid reagent in it and mounted directly on the housing of the reagent inlet assembly or on the plug the windows of the said housing by means of a latch; according to the second embodiment, the housing of the said assembly is made in the form of a bypass line installed on the pipeline, while the reagent module is is removable and hydraulically permeable and consisting of at least one autonomous hydraulically permeable chamber with a solid reagent placed in it, while the bypass line is equipped with at least one window with a plug for loading the reagent module and to monitor the presence of solid reagent during operation, and on the pipeline and / or bypass line, locking and control devices are additionally installed that provide the possibility of transporting along the pipeline and bypass line at the same time or pumped products.

The specified technical result is provided according to the third embodiment of the proposed system to prevent the formation of deposits in the pipeline, including in areas with complex terrain, consisting of a pipeline and a reagent inlet node, while the new one is that the reagent inlet node is placed inside the pipeline and fixed on the window plug, which is made on the pipeline for placement in the last reagent input unit, and is removable and hydraulically permeable in the form of a reagent module, consisting of at least at least, from one autonomous hydraulically permeable chamber with a solid reagent placed in it.

In the system in three variants, the autonomous hydraulically permeable chamber of the reagent module is made in the form of a mesh and / or perforated container with a solid reagent, and the container is made of metal or non-metallic material. Moreover, the mesh pitch of the mesh container is 5-50 mm.

In all cases, the solid reagent is placed in an autonomous hydraulically permeable chamber of the reagent module in the form of granule grains, drafts, and cylinders.

According to the first and third options, the autonomous hydraulically permeable chamber of the reagent module is made in the form of a shelf rack, on the shelves of which a solid reagent is horizontally placed either in mesh or perforated containers.

According to the first and third options, the autonomous hydraulically permeable chamber of the reagent module is made in the form of a shelf rack, on the shelves of which a solid reagent is horizontally placed or in the form of a mesh cassette with hydraulically permeable vertical partitions between which a solid reagent is placed.

According to the first and second options, a shut-off and control device is installed on the branch reagent inlet node and / or in the pipeline, and the branch reagent inlet node is also equipped with a pressure regulator.

According to the second variant, an autonomous hydraulically permeable chamber with a solid reagent placed in it is installed on a section of the bypass line parallel to the direction of flow in the pipeline.

According to the first and second options, if there are several autonomous hydraulically permeable chambers with a solid reagent as a reagent module, they are placed in the housing of the input unit with a gap to each other.

In the second embodiment, the reagent module is fixed in the bypass line with a latch mounted on the plug.

According to the third option, a viewing window is installed on the pipeline, next to the window for placement in the pipeline of the reagent input unit.

The specified technical result is achieved due to the following.

Due to the fact that a window with a plug is made in the housing of the reagent input unit, it became possible to freely load or remove the reagent module and monitor the presence of the reagent during operation.

Due to the fact that the reagent module is removable, it is possible to repair, replace or dismantle it if it is not necessary, and it is also easy to fill it with reagent.

The implementation of the reagent module hydraulically permeable creates the conditions for uniform washing of the reagent in it by the products transported through the pipeline, which in turn leads to leaching of the optimal amount of reagent necessary to prevent the formation of deposits.

Due to the fact that the reagent module consists of at least one autonomous hydraulically permeable chamber, it becomes possible to load an increased amount of solid reagent and all of it will be washed by the transported products, which increases the efficiency of the system.

Due to the fact that the solid reagent is loaded horizontally or vertically into the hydraulically permeable chambers, a significant local hydraulic resistance is created, which greatly perturbs the flow, causing turbulence, which in turn leads to a more complete flushing of the reagent with the transported liquid and high efficiency indicators to prevent the formation of deposits.

Due to the fact that the chamber of the reagent module is mounted directly on the housing of the reagent input unit or by means of a latch on the window cover of the said housing, the possibility of its unplanned movement in the housing or displacement relative to the axis is excluded, which increases the reliability of the system as a whole.

Due to the fact that the chamber of the reagent module is made in the form of a mesh and / or perforated container, the solid reagent is washed evenly and the amount of reagent necessary to prevent the formation of deposits enters the transported medium.

Due to the fact that the container is made of metallic or non-metallic material, the process of selecting material for the manufacture of this container is simplified.

Due to the fact that the mesh step of the mesh container is 5-50 mm, the reagent is washed out more evenly.

The uniformity of washing also contributes to the fact that the reagent is placed in the form of grains, pellets, checkers, cylinders, so that the reagent enters the optimum amount into the transported liquid.

Due to the installation of a shut-off and regulating device on the branch unit of the reagent input, the reagent is controlled and loaded without stopping the transport of the product.

By supplying the body of the branch reagent inlet node with a pressure regulator, it became possible to equalize the pressure in the system and pipeline for a more successful transportation process.

Due to the use of a bypass line (according to the second variant), a symmetric flow pattern arises: upward → horizontal → downward flows. This contributes to a more intensive washing of the reagent while maintaining optimal pressure and a uniform flow of reagent into the total flow.

Due to the installation of a hydraulically permeable chamber in a section of the bypass line parallel to the direction of flow in the pipeline, the reagent is washed out more uniformly.

When several autonomous hydraulically permeable chambers with a solid reagent are installed with a gap to each other, the flushing of these chambers takes place more intensively, and the ratio of “washed reagent to transported products” is the most optimal.

The location according to the third embodiment of the reagent input unit in the pipeline cavity allows the flow to intensively wash permeable chambers without changing the direction of movement.

Due to the fact that the permeable chamber is made in the form of a rack with horizontal loading of a solid reagent into it, washing the latter occurs without reducing the pressure in the pipeline.

Due to the placement of the solid reagent between the vertical partitions of the mesh cassette, flow perturbation occurs with the formation of vortices, and therefore, the reagent is washed out more intensively.

When a viewing window is installed on the pipeline, next to the reagent input unit, it is possible to control the amount of reagent without dismantling the main structure.

The invention is illustrated by drawings, where figure 1, 2, 3 shows a General view of the system according to the first, second and third options, respectively.

The proposed system for all three options consists of a pipeline 1 and a reagent inlet unit 2, and in the first and second versions this node 2 is made branched, and in the third version it is installed inside the pipeline 1. The reagent inlet node 2 of the system (according to the first and second options ) contains a housing 3 (FIGS. 1 and 2), in which a reagent module 4 is placed. Said module 4 in all three variants includes autonomous hydraulically permeable chambers 5, made, for example, in the form of a shelving rack or mesh cassette with a horizontal or vert Kalnoy loading therein the solid reactant 6. Reagent module 4 may be mounted directly on the body 3 or on the plug 7 of the window 8, which serves for loading reagent module 4 and the control over the expenditure of solid reagent 6.

In the third embodiment, the reagent module 4 (Fig. 3) is mounted on the plug 9 of the window 10, which is cut out on the pipeline 1.

According to the second embodiment, a viewing window 11 can be made on the housing 3.

For all three options for regulating the direction of flow and its intensity, shut-off and control devices 12, 13 are installed.

The proposed system according to the first and second options works as follows.

On the problematic section of the pipeline 1 (for example, on the section where the pipeline passes through the ravine), insert the body 3 of the branch unit 2 of the reagent inlet (the diameter of the body 3 according to the first embodiment is chosen so that when the product being pumped is transported through pipeline 1, this product goes into case 3 and washed there a solid reagent). A window 8 is made in the housing 3 and is provided with a plug 7. If the housing 3 is in the form of a bypass line (Fig. 2), then an inspection window 11 can be additionally made on it to monitor the content of the solid reagent in the reagent module 4. Then, a reagent module 4 is connected to the plug 7 (in the bypass line it is fixed to the walls of the housing 3 by the holders 14), consisting of at least one hydraulically permeable chamber 5, for example, in the form of a mesh container filled with granular solid reagent 6. Further to labor the closure-regulating device 12 (valve) is opened in the duct 1 and the stream of transported products 15 passes through the duct 1 through the reagent inlet 2, washes the solid reactant 6, partially dissolving it, and then goes into the pipeline 1. Varying the number of chambers 5 in the reactant module 4 , it is guaranteed to provide the required period of time to protect the pipeline from deposits (for example, for a month, quarter, six months or a year). After this time, the chambers 5 are replaced by personnel serving the pipeline by closing the plugs 12 or 13, removing the empty chamber 5 through the window 8, filling these chambers 5 with new solid reagent 6 and installing them in the housing 3 of the reagent input unit 2. Then the plugs 12 or 13 are opened and the process of transporting the medium 15 through the pipeline 1 continues.

According to the third variant, the solid reagent inlet unit 2 is placed inside the pipeline 1 and taking into account that its reagent module consists of hydraulically permeable chambers 5 (for example, in the form of a shelf rack with mesh containers with solid reagent 6 located on its shelves), the transported stream freely washes the solid reagent, partially dissolving it, and goes further into the pipeline 1.

The proposed systems (according to the second and third options) were tested on the main pipeline passing in the Perm Prikamye and on flow lines of the wells.

The results obtained during the tests are shown in the table.

Table Test results of the proposed systems for the prevention of deposits in the oil and gas environment No. p / p Test system Installation location Type and volume of transport. production The number of cameras in the input node and the name of the solid reagent The period of the pipeline without repair before set. the system after set. the system one System according to the second embodiment On flow lines of the pipeline V = 60 m ³ / day. produced fluid from a well 1 camera with LCD 138 165 2 cameras with LCD 138 192 2 The system according to the third option Inside the oil transport pipeline V = 200 m ³ / day. pumped liquid 2 cameras with LCD 230 284 4 cameras with LCD 230 340 Note: ICD solid reagent is designed to prevent asphalt-resin-paraffin deposits

The data given in the table show that the proposed systems reliably and reliably ensure the prevention of deposits of asphalt-resin-paraffin substances.

Considering that the proposed systems can work for a longer time without replacing the solid reagent-inhibitor, this will allow us to talk about their efficiency and ease of maintenance

The proposed system allows without the use of complex technical means (pumps, drives) to proportionally and evenly dose a solid reagent (by washing out) on any part of the pipeline, including in areas with complex terrain.

Moreover, the proposed system is simple, cheap and reliable and provides an optimal and constant ratio of the dose of reagent to the consumption of transported products in the pipeline.

Claims (28)

1. The system for preventing the formation of deposits in the pipeline, including in areas with difficult terrain, consisting of a pipeline and a hydraulically connected branch reagent input node containing a housing rigidly connected to the pipeline with a reagent module located inside it, characterized in that in the case of the reagent input unit, a window is made with a plug for loading the reagent module and monitoring the presence of a solid reagent in it during operation, while the reagent module is removable m, hydraulically permeable and which consists of at least one autonomous hydraulically permeable chambers with horizontal or vertical loading the solid reactant therein, and is fixed directly to the input unit of the reagent on the plug housing or a window of said housing. 2. The system according to claim 1, characterized in that if there are several autonomous hydraulically permeable chambers with a solid reagent as a reagent module, they are placed in the housing of the reagent input unit with a gap to each other. 3. The system according to claim 1, characterized in that the autonomous hydraulically permeable chamber of the reagent module is made in the form of a shelf rack, on the shelves of which a solid reagent is horizontally placed. 4. The system according to claim 1, characterized in that the autonomous hydraulically permeable chamber of the reagent module is made in the form of a mesh cassette, with hydraulically permeable vertical partitions, between which a solid reagent is placed. 5. The system according to claim 1, characterized in that the autonomous hydraulically permeable chamber of the reagent module is made in the form of a mesh and / or perforated container with a solid reagent. 6. The system according to claim 5, characterized in that the mesh or perforated container is made of metallic or non-metallic material. 7. The system according to claim 5 or 6, characterized in that the mesh pitch of the mesh container is 5-50 mm. 8. The system according to claim 1, characterized in that the solid reagent is placed in a self-contained hydraulically permeable chamber of the reagent module in the form of granule grains, checkers, cylinders. 9. The system according to claim 1, characterized in that a shut-off and control device is installed on the branch reagent input unit or on the pipeline. 10. The system according to claim 1, characterized in that the housing of the branch unit of the input reagent is equipped with a pressure regulator. 11. System for preventing the formation of deposits in the pipeline, including in areas with difficult terrain, consisting of a pipeline and from a hydraulically connected branch reagent input node, comprising a housing rigidly connected to the pipeline with a reagent module located inside it, characterized in that the housing of the said node is made in the form of a bypass line installed on the pipeline, while the reagent module is made removable and hydraulically permeable and consisting of at least one autonomous hydraulically permeable chamber with a solid reagent placed in it, while the bypass line is equipped with at least one window with a plug for loading the reagent module and to monitor the presence of a solid reagent in it during operation, moreover, on the pipeline and / or bypass line In addition, shut-off and control devices are installed that provide the possibility of transporting simultaneously or separately pumped products through the pipeline and bypass line. 12. The system according to claim 11, characterized in that a stand-alone hydraulically permeable chamber with a solid reagent placed in it is installed on a section of the bypass line parallel to the direction of flow in the pipeline. 13. The system according to claim 11, characterized in that if there are several autonomous hydraulically permeable chambers with a solid reagent as a reagent module, they are placed in the bypass line cavity with a gap to each other. 14. The system according to claim 11, characterized in that the autonomous hydraulically permeable chamber of the reagent module is made in the form of a mesh and / or perforated container with a solid reagent. 15. The system according to 14, characterized in that the mesh or perforated container is made of metallic or non-metallic material. 16. The system of claim 14 or 15, characterized in that the mesh pitch of the mesh container is 5-50 mm. 17. The system according to claim 11, characterized in that the solid reagent is placed in a self-contained hydraulically permeable chamber of the reagent module in the form of granule grains, checkers, cylinders. 18. The system according to claim 11, characterized in that the reagent module is fixed in the bypass line with a latch mounted on the plug. 19. The system according to claim 11, characterized in that the bypass line is equipped with a pressure regulator. 20. System for preventing the formation of deposits in the pipeline, including in areas with difficult terrain, consisting of a pipeline and a reagent inlet node, characterized in that the reagent inlet node is placed inside the pipeline and mounted on the window plug that is made on the pipeline for placement in the last node input reagent, and made removable and hydraulically permeable in the form of a reagent module, consisting of at least one autonomous hydraulically permeable chamber with a solid reagent. 21. The system according to claim 20, characterized in that the autonomous hydraulically permeable chamber with a solid reagent placed in it is made in the form of a shelf rack, on the shelves of which a solid reagent is horizontally placed. 22. The system according to item 21, wherein the solid reagent on the shelves of the shelving rack is placed in mesh and / or perforated containers. 23. The system according to item 22, wherein the mesh or perforated containers are made of metal or non-metallic material. 24. The system according to claim 20, characterized in that the autonomous hydraulically permeable chamber of the reagent module is made in the form of a mesh cassette with hydraulically permeable vertical partitions, between which a solid reagent is placed. 25. The system according to paragraph 24, wherein the stand-alone hydraulically permeable chamber of the reagent module is made in the form of a mesh and / or perforated container with a solid reagent. 26. The system according to item 22, or 23, or 24, or 25, characterized in that the grid spacing of the mesh container is 5-50 mm. 27. The system according to claim 20, characterized in that the solid reagent is placed in a self-contained hydraulically permeable chamber of the reagent module in the form of granule grains, drafts, cylinders. 28. The system according to claim 20, characterized in that the observation window is installed on the pipeline next to the window for placement in the pipeline of the reagent input unit.

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