RU90482U1 - Borehole camera Garipova - Google Patents

Abstract

1. A downhole chamber, consisting of a carrier pipe, the ends of which have either external or internal, or external and internal connecting threads, a pocket made with internal bores, seating surfaces and at least one passage hole located in the wall, and representing a portion of the pipe, the ends of which have either an external or internal, or an external and internal connecting thread, the pocket is made with a plugged or open lower end of the upper tip, consisting of interconnected at the interface between the outer surfaces of the guide element having an internal cavity and the tubular element, the internal cavities of which communicate with each other by means of a cutout located in the wall of the tubular element and configured to allow the cable tool to pass through it, a carrier is installed at the lower end of the tubular element the pipe by means of an internal connecting thread or without a thread, and an inner mandrel is installed in the upper end of the tubular element by means of an internal connecting thread or without thread, made with the possibility of rotation and direction of the cable tool, the inner cavity of the guide element is made with the possibility of directed passage through it into the pocket of the cable tool, a pocket is installed in the lower part of the guide element by internal connecting thread or without thread, the supporting pipe and pocket located parallel or oblique to each other. ! 2. The downhole chamber according to claim 1, characterized in that the pocket and the support pipe are equipped with a telescopic connection

Description

The utility model relates to the oil industry, namely, to downhole equipment and can be used in the production of fluid (oil, gas, etc.) or pumping a working agent into a well with one or more layers.

The well-known "CAMERA WELL" containing a supporting pipe, a pocket, an orienting nipple, an upper tip, a hydraulic channel (Patent No. 2260108, ЕВВ 23/02 op. 09/10/2005).

A disadvantage of the known solution is the design complexity, high metal consumption, due to the complex placement of structural elements, namely the placement of the guide pipe in the form of an insert pocket inside the body of the carrier pipe, it is very difficult and shortens the life of the device is the welded design of the upper and lower tips overlapping the holes of the carrier pipe into the guide tube with the formation of a passage channel for installation in the equipment pocket.

Closest to the proposed utility model is the “Sharifov Well Chamber for Removable Valves”, which includes a shirt in the form of a pipe section, an upper tip with an upper pipe thread and an inner mandrel for rotation and direction of the cable tool — a cantilever deflector, a pocket with internal bores, landing surfaces and with one or more passage channels, with the possibility of hydraulic communication of its cavity with the space behind the pocket and the jacket, a guide element for a removable valve, p and this shirt and pocket have an external or internal, or external and internal connecting threads, and the upper tip is made with a threaded or threaded and welded connection with a shirt and pocket (Patent No. 2292439, ЕВВ 23/03; Е21В 34/06, op. 01/27/2007, prototype).

The disadvantage of the prototype is the design complexity, high metal consumption, due to the complex placement of structural elements, namely the placement of a pocket inside a large shirt. Rigid fastening of the pocket to the inner surface of the shirt leads to a weakening of the structure, a reduction in its life, in addition, this design is not repairable and involves one-time use in case of damage, for example, corrosion or salt deposits in the pocket, limiting the use of the structure due to the inability to work a plunger and geophysical instruments that get stuck in the cavity of the upper tip in the area of the guides. In addition, when fluid exits from the valve into the pocket and into the annulus of the well, significant hydraulic resistances are obtained, because, unlike a valve with several radially located through holes - hydraulic channels, there is only one hydraulic outlet channel in the pocket when installing a gas lift valve only one hole is located opposite the pocket hole, and the rest go into the grooved pocket groove, which leads to a rapid erosion of the wall of the carrier pipe of the borehole chambers .

The proposed technical solution avoids the above-mentioned disadvantages, including simplifying the design and extending the life of the Well Chamber, also allows repair work of the Well Chamber, namely, to separately replace or repair the supporting pipe and / or pocket, depending on their wear, allows repair milling work inside the upper tip in the inner cavity of the guide element to create clear boundaries, including a groove, groove or protrusion, which will allow to refuse from installing removable guides that wear out quickly, break down and often lead to emergency situations.

This goal is achieved in that the downhole chamber includes a support pipe, the ends of which have either external or internal, or external and internal connecting threads, a pocket made with internal bores, seating surfaces and at least one passage hole located in the wall, and representing a portion of the pipe whose ends have either an external or internal, or an external and internal connecting thread, the pocket is made with a plugged or open lower end, the upper Chevron, consisting of the outer surfaces of the guide element having an internal cavity interconnected at the interface, and the tubular element, the internal cavities of which communicate with each other by means of a cutout located in the wall of the tubular element and configured to allow the cable tool to pass into the lower end a support tube is installed of the tubular element by means of an internal connecting thread or without a thread, and an inner frame is installed at the upper end of the tubular element by means of internal connecting thread or without thread, made with the possibility of rotation and direction of the cable tool, the inner cavity of the guide element is made with the possibility of directed passage through it of the pocket of the cable tool, a pocket is installed in the lower part of the guide element by internal connecting thread or without thread, the supporting pipe and the pocket are parallel or oblique to each other, in addition, the pocket and the supporting pipe are equipped with a telescopic connection, which connects the open lower end of the pocket with the internal cavity of the carrier pipe provided with an opening in the wall, or hermetically connects the hole in the wall of the pocket with the internal cavity of the carrier pipe provided with an opening in the wall, the lower end of the carrier pipe is muffled or open, in which the adapter or sub is installed (Option 1).

The downhole chamber includes a pocket made with internal bores, seating surfaces, and at least one through hole located in the wall, and representing a portion of the pipe, the ends of which have either external or internal, or external and internal connecting threads, pocket made with a muffled or open lower end, the upper tip, consisting of interconnected at the interface between the outer surfaces of the guide element having an internal cavity, and a tubular elements whose inner cavities communicate with each other by means of a cutout located in the wall of the tubular element and configured to extend the cable tool therein, the lower end of the tubular element is muffled and an inner mandrel is installed at the upper end of the tubular element with or without a thread, made with the possibility of rotation and direction of the cable tool, the inner cavity of the guide element is made with the possibility of directional passing through it into the pocket of the rope tool, a pocket is installed in the lower part of the guide element by means of an internal connecting thread or without a thread (Option 2),

in addition, the pipe section as a pocket is made of tubing or drill pipe, the upper tip is made of monolithic or prefabricated, the pocket is made of monolithic or prefabricated and an adapter or sub is installed in its lower part, and / or a storage container on the side surface of the internal cavity the protrusion element has a protrusion for directed passage through it into the pocket of the rope tool, and the protrusion is made in the form of overlays, on the lateral surface of the inner cavity of the guide element there is a groove or groove for directed passage through it into the pocket of a rope tool, the pocket is made of corrosion-resistant material or material with an anti-corrosion coating, the storage container is a pipe or pipe, the pocket and / or upper tip are made of non-magnetic material, made of material or have a coating of heat-, acid-, oil-resistant material, all internal and external surfaces of the borehole chamber are streamlined and with smoothed protrusions, through holes are located rad either horizontally or vertically, evenly or unevenly, in one row or several rows and oriented in the opposite direction from the carrier pipe, and also equipped with a protective element.

The figure 1 shows the borehole chamber in section with a monolithic embodiment of the upper tip (Option 1), figure 2 shows the borehole chamber in section with a composite embodiment of the upper tip and with a telescopic connection (Option 1), figure 3 shows a section aa children poses 5 and 7, figure 4 shows a section bb det. 5 and 7, figure 5 shows the Wellbore in the context with a monolithic execution of the tubular element of the upper tip with a plugged end (Option 2).

OPTION 1

The downhole chamber consists of a carrier pipe 1, an upper tip 2, an inner mandrel 3 and a pocket 4.

The upper tip 2 is interconnected at the interface between their outer surfaces of the guide element 5 having an internal cavity 6 and a tubular element 7. The upper tip 2 is prefabricated or monolithic.

The inner cavities 6 and 8 of the guide 5 and the tubular elements 7 communicate with each other by means of a cut-out 9 located in the wall of the tubular element 7 and configured to extend the cable tool from the inner cavity 8 of the tubular element 7 into the inner cavity 6 of the guide element 5, i.e. e. the size of the cutout 9 is comparable to the diameter of the wireline tool — a tool for installing or removing a gas lift valve, which makes it possible to safely use a plunger and a geophysical instrument with a diameter larger than the size of the cutout 9.

The tubular element 7 is a pipe section, such as tubing. The lower end of the tubular element 7 is made with an internal connecting thread or without a thread, and a supporting pipe 1 is installed in it. The upper end of the tubular element 7 is made with an internal connecting thread or without a thread, which is connected to the inner mandrel 3.

The inner cavity 6 of the guide element 5 is made with the possibility of directional passage through it into the pocket 4 of the rope tool and is designed to accurately install or remove the gas lift valve from the pocket 4. For the directed passage of the rope tool into the pocket 4 on the side surface of the inner cavity 6 of the guide element 5, a protrusion groove or groove. In this case, the protrusion is made, for example, in the form of overlays (not shown in Fig.).

In the lower part of the guide element 5, a pocket 4 is installed using an internal connecting thread or without thread.

The inner mandrel 3 is made with the possibility of rotation and direction of the cable tool in the form of a cantilever deflector and is installed by means of an internal connecting thread or without thread in the upper tip 2.

The support pipe 1 is a pipe section, for example, tubing, the ends of which have either external, internal, or external and internal connecting threads or grooves for connection with oilfield equipment. The lower end of the carrier pipe 1 is muffled or open with an internal connecting thread or without a thread, to which an adapter or sub 10 is connected.

Pocket 4 is a pipe section, for example tubing, the ends of which have either external or internal, or external and internal connecting threads. The pocket 4 is made monolithic or prefabricated and with internal bores 11 and 12, seating surfaces 13 and 14 and is equipped with at least one through hole 15 located in the wall for hydraulic communication with the annulus behind the pocket 4.

Pocket 4 is made with a muffled or open lower end into which an adapter or sub 10 is installed, and / or a storage container. In addition, the pocket 4 is made of a corrosion-resistant material, for example, non-ferrous metal, polymer, or a material with an anti-corrosion coating, for example, made by the method of chromium plating, phosphating of a metal surface.

To prevent erosion of the wall of the carrier pipe 1, the fluid flow exiting at least one passageway 15 located in the wall of the pocket 4, the passageways 15 are located at least in one row, radially or vertically, uniformly or unevenly along the length the circumference of the pocket 4 or vertically of the pocket 4 and are oriented in the opposite direction from the carrier pipe 1. In addition, the through holes 15 are provided with a protective element, for example, in the form of a mesh (not shown in FIG.) For protection against debris.

A storage container is a pipe section, pipe or pipe and is designed to collect and accumulate garbage and is necessary in cases where it is not possible to completely remove a damaged gas lift valve, when parts of the gas lift valve fragments are moved from the inner cavity of pocket 4 into the storage container under the influence of a wire rope tool 4 ( in Fig. not shown).

The carrier pipe 1 and pocket 4 are placed parallel or oblique to each other.

The carrier pipe 1, the tubular element 7 and the pocket 4 in cross section are a circle or an ellipse.

For hydraulic communication of the internal cavities of the pocket 4, the carrier pipe 1 with the annulus through the through holes 15 in the wall of the carrier pipe 1, a hole 17 is made.

The pocket 4 and the support pipe 1 are additionally equipped with a telescopic connection 18, hermetically connecting the pocket 4 with the internal cavity of the support pipe 1. The tight connection of the pocket 4 with the support pipe 1 is carried out by means of a sealing seal 19.

In the case when the pocket 4 is made with an open lower end, the telescopic connection 18 hermetically connects the open lower end of the pocket 4 with the inner cavity of the carrier pipe 1, provided with an opening 17 in the wall.

In the case when the pocket 4 is made with a muffled lower end, the telescopic connection 18 hermetically connects the hole in the wall of the pocket 4 with the internal cavity of the carrier pipe 1 provided with an opening 17 in the wall.

In the case of hard - welding of the telescopic connection of the pocket 4 with the carrier pipe 1 can do without sealing elements.

To improve the permeability of the cable tool, all internal and external surfaces of the borehole chamber are streamlined, with smooth protrusions of the constituent elements.

The storage container is a pipe or pipe.

Pocket 4 and / or upper tip 2 are made of non-magnetic material, made of material or have a coating of thermo-, acid-, oil-resistant material.

OPTION 2. The downhole chamber consists of an upper tip 2, an inner mandrel 3 and a pocket 4.

The upper tip 2 is interconnected at the interface between their outer surfaces of the guide element 5 having an internal cavity 6 and the tubular element 7. The upper tip 2 is prefabricated or monolithic.

The inner cavities 6 and 8 of the guide 5 and the tubular elements 7 communicate with each other by means of a cut-out 9 located in the wall of the tubular element 7 and configured to extend the cable tool from the inner cavity of the tubular element 7 into the inner cavity of the guide element 5, i.e. the size of the cut-out 9 is comparable to the diameter of the cable tool - a tool for installing or removing a valve, which allows the safe use of a plunger and a geophysical instrument.

The tubular element 7 is a pipe section, such as tubing. The lower end of the tubular element 7 is muffled 20, for example, by means of a plug. The upper end of the tubular element 7 is made with an internal connecting thread or without thread, in which the inner mandrel 3 is installed.

The inner cavity 6 of the guide element 5 is made with the possibility of directional passage through it into the pocket 4 of the rope tool and is designed to accurately install or remove the gas lift valve from the pocket 4. For the directed passage of the rope tool into the pocket 4 on the side surface of the inner cavity 6 of the guide element 5, a protrusion groove or groove. In this case, the protrusion is made, for example, in the form of overlays (not shown in Fig.).

In the lower part of the guide element 5, a pocket 4 is installed using an internal connecting thread or without thread.

The inner mandrel 3 is made with the possibility of rotation and direction of the cable tool in the form of a cantilever deflector and is installed by means of an internal connecting thread or without thread in the upper tip 2.

Pocket 4 is a pipe section, for example tubing, the ends of which have either external or internal, or external and internal connecting threads. The pocket 4 is made monolithic or prefabricated and with internal bores 11 and 12, landing surfaces 13 and 14 and at least one through hole 15 located in the wall. Pocket 4 is made with a muffled or open lower end into which an adapter or sub 10 is installed, and / or a storage container. Pocket 4 is made of a corrosion-resistant material, for example, non-ferrous metal, polymer, or a material with an anti-corrosion coating, for example, chrome steel.

The tubular element 7 and the pocket 4 in cross section is a circle or ellipse.

To improve the permeability of the cable tool, all internal and external surfaces of the borehole chamber are streamlined, with smooth protrusions of the constituent elements.

Option 1 differs from Option 2 in that the wellbore of Option 2 does not contain a support pipe 1 with all the structural elements resulting from it.

The downhole camera operates as follows (OPTION 1).

The downhole chamber using connecting pipes (top and bottom) is connected to the tubing, lowered into the well and placed at a given depth. Then, with the help of cable technology and rope tools, the necessary equipment is installed.

For this, by means of a cable tool in the form of a cantilever diverter type ОКС (hereinafter referred to as the ОКС tool), a removable valve, for example, a gas lift valve (not shown), is installed in pocket 4. First, the ACS tool is lowered into the carrier pipe 1 just below the borehole chamber, then it is lifted to ensure the interaction of the inner mandrel 3 with the ACS tool, as a result of this interaction, they begin to deflect, rotate the ACS tool and thereby direct the gas-lift valve towards the pocket 4 into the internal cavity 6 of the guide element 5 through a cutout 9 in the wall of the tubular element 7. Next, lowering the tool ACS, enter the gas lift valve into the seating surface 13 of the pocket 4 and install it. When the lock of the gas lift valve in the form of, for example, a collet, is fixed in a certain place on the seating surface 14 of the pocket 4, and the cuffs of the gas lift valve (not shown in the figure) are installed in the inner bores 11 and 12 of the pocket 4, the gas lift valve is installed. In this case, the hydraulic channels of the gas-lift valve are installed opposite the landing surface 13, which has at least one passage opening 15.

The gas-lift valve installed in the borehole chamber is removed using an ACS tool connected to a fishing tool, which is initially lowered by wire below the borehole chamber.

When lifting the tool up, a process similar to the described installation of the gas lift valve is carried out, namely, after the orientation and operation of the ACS tool, the fishing tool enters the inner cavity 6 of the guide element 5 through a cutout 9 in the wall of the tubular element 7, after which the gas lift valve and its extraction from pocket 4 and then from the well.

The downhole chamber when using other additional structural elements works as follows (OPTION 1).

The borehole chamber is installed in the borehole on the tubing with the possibility of transferring gas or liquid from the annulus to the inner cavity of the tubing, that is, using a telescopic connection 18 and a through hole 15.

Gas or liquid is supplied through the annulus, which passes through at least one passage hole 15 in the wall of the pocket 4, then through a standard one-piece gas lift valve and telescopic connection 18 enters through the hole 17 inside the carrier pipe 1. Thus, the annulus is connected well space with an internal tubing cavity. At the same time, gas or liquid, getting into the tubing, performs the work of lifting the fluid through the tubing, providing a gas-lift production method.

If instead of a standard gas-lift valve, for example, a valve with an opening in the valve head is used, gas or liquid can enter the carrier pipe 1 and, accordingly, the tubing internal cavity, by using a well chamber for removable valves, in which pocket 4 is made with a drowned end.

The downhole camera operates as follows (OPTION 2).

Installation of the gas lift valve in pocket 4 is carried out at the wellhead, then using connecting pipes (above and below) are connected to the tubing, lowered into the well and placed at a predetermined depth. Then, with the help of cable technology and rope tools, the necessary equipment is installed.

The proposed technical solution allows to simplify the design, reduce metal consumption by using a supporting pipe and valve of a smaller diameter, and also allows to extend the life of the borehole chamber as a result of the possibility of separate replacement or repair of the supporting pipe or pocket depending on their wear, which allows them to be used repeatedly .

The proposed design allows you to refuse to install removable guides that quickly wear out, break down and often lead to emergency situations and make it possible to carry out repair milling operations inside the upper tip in the inner cavity of the guide element to create clear boundaries, including a groove, groove, or protrusion. In addition, in the case of option 1, the orientation of the through holes in the opposite direction from the carrier pipe avoids erosion and damage and increases the life of the carrier pipe.

Claims (34)

1. A downhole chamber, consisting of a carrier pipe, the ends of which have either external or internal, or external and internal connecting threads, a pocket made with internal bores, seating surfaces and at least one passage hole located in the wall, and representing a portion of the pipe, the ends of which have either an external or internal, or an external and internal connecting thread, the pocket is made with a plugged or open lower end of the upper tip, consisting of interconnected at the interface between the outer surfaces of the guide element having an internal cavity and the tubular element, the internal cavities of which communicate with each other by means of a cutout located in the wall of the tubular element and configured to allow the cable tool to pass through it, a carrier is installed at the lower end of the tubular element the pipe by means of an internal connecting thread or without a thread, and an inner mandrel is installed in the upper end of the tubular element by means of an internal connecting thread or without thread, made with the possibility of rotation and direction of the cable tool, the inner cavity of the guide element is made with the possibility of directed passage through it into the pocket of the cable tool, a pocket is installed in the lower part of the guide element by internal connecting thread or without thread, the supporting pipe and pocket located parallel or oblique to each other. 2. The downhole chamber according to claim 1, characterized in that the pocket and the supporting pipe are provided with a telescopic connection that hermetically connects the open lower end of the pocket with the internal cavity of the supporting pipe provided with an opening in the side wall. 3. The downhole chamber according to claim 1, characterized in that the pocket and the supporting pipe are equipped with a telescopic connection, hermetically connecting the hole in the side wall of the pocket with the internal cavity of the supporting pipe provided with an opening in the side wall. 4. The downhole chamber according to claim 1, characterized in that the lower end of the carrier pipe is muffled or open. 5. The downhole chamber according to claim 1, characterized in that the lower end of the carrier pipe is equipped with an adapter or sub. 6. The downhole chamber according to claim 1, characterized in that the pipe section as a pocket is made of tubing or drill pipe. 7. The downhole chamber according to claim 1, characterized in that the upper tip is made monolithic or prefabricated. 8. The downhole chamber according to claim 1, characterized in that on the side surface of the inner cavity of the guide element there is a protrusion in the form of overlays. 9. The downhole chamber according to claim 1, characterized in that a groove or groove is made on the lateral surface of the inner cavity of the guide element. 10. The downhole chamber according to claim 1, characterized in that the pocket is made monolithic or composite. 11. The downhole chamber according to claim 1, characterized in that the lower end of the pocket is equipped with an adapter or sub. 12. The downhole chamber according to claim 1, characterized in that the lower end of the pocket is equipped with a storage container in the form of a pipe or pipe. 13. The downhole chamber according to claim 1, characterized in that the pocket is made of a corrosion-resistant material or a material with a corrosion-resistant coating. 14. The downhole chamber according to claim 1, characterized in that the pocket and / or upper tip are made of non-magnetic material and are made of thermo-, acid-, oil-resistant material or have a coating of thermo-, acid-, oil-resistant material. 15. The borehole chamber according to claim 1, characterized in that all the internal and external surfaces of the borehole chamber are streamlined and with smooth protrusions. 16. The downhole chamber according to claim 1, characterized in that the passage holes are provided with a protective element. 17. The downhole chamber according to claim 1, characterized in that the through holes are located radially or vertically, at least in one row. 18. The downhole chamber according to claim 1, characterized in that the through holes are evenly or unevenly along the circumference of the pocket or vertically. 19. The downhole chamber according to claim 1, characterized in that the passage openings are oriented in the opposite direction from the carrier pipe. 20. A downhole chamber, consisting of a pocket made with internal bores, seating surfaces and at least one passage hole located in the wall, and representing a section of the pipe, the ends of which are either external or internal, or external and internal connecting threads, the pocket is made with a plugged or with an open lower end, the upper tip, consisting of interconnected at the interface between the outer surfaces of the guide element having an internal cavity, and the tubular element, the internal cavities of which communicate with each other through a cutout located in the wall of the tubular element and made with the possibility of passage of the rope tool in it, the lower end of the tubular element is muffled, and the inner mandrel is installed with an internal connecting thread or without thread made with the possibility of rotation and direction of the cable tool, the inner cavity of the guide element is configured to a systematic way of passing it into the rope tool pocket at the bottom of the guide member is installed inside the pocket by the connecting threads or unthreaded. 21. The downhole chamber according to claim 20, characterized in that the pipe section as a pocket is made of tubing or drill pipe. 22. The downhole chamber according to claim 20, characterized in that the upper tip is made monolithic or prefabricated. 23. The downhole chamber according to claim 20, characterized in that on the side surface of the inner cavity of the guide element there is a protrusion in the form of overlays. 24. The downhole chamber according to claim 20, characterized in that a groove or groove is made on the side surface of the inner cavity of the guide element. 25. The downhole chamber according to claim 20, characterized in that the pocket is made monolithic or composite. 26. The downhole chamber according to claim 20, characterized in that the lower end of the pocket is equipped with an adapter or sub. 27. The downhole chamber according to claim 20, characterized in that the lower end of the pocket is equipped with a storage container in the form of a pipe or pipe. 28. The downhole chamber according to claim 20, characterized in that the pocket is made of a corrosion-resistant material or of a material with an anti-corrosion coating. 29. The downhole chamber according to claim 20, characterized in that the pocket and / or upper tip are made of non-magnetic material and are made of thermo-, acid-, oil-resistant material or have a coating of thermo-, acid-, oil-resistant material. 30. The borehole chamber according to claim 20, characterized in that all internal and external surfaces of the borehole chamber are streamlined and with smooth protrusions. 31. The downhole chamber according to claim 20, characterized in that the through holes are provided with a protective element. 32. The downhole chamber according to claim 20, characterized in that the through holes are located radially or vertically, at least in one row. 33. The downhole chamber according to claim 20, characterized in that the through holes are evenly or unevenly along the circumference of the pocket or vertically. 34. The downhole chamber according to claim 20, characterized in that the passage holes are oriented in the opposite direction from the carrier pipe.