RU160010U1 - THERMAL ISOLATING DIRECTION OF A DRILL WELL - Google Patents

Abstract

1. The thermally insulating direction of the borehole, made collapsible, each section of which contains an inner and outer pipe and a heat-insulating material placed between them, characterized in that it consists of two or more sections, each of which, in the joint zone, has protruding the outer pipe is the end of the inner pipe, the lower end of the inner pipe of the upper section being connected to the upper end of the inner pipe of the lower section by means of a threaded coupling, wherein the junction of the outer pipes of each section is per it is covered by a shell, and each cavity between the shell and connected by means of a threaded coupling of the inner pipe is filled with heat-insulating material. 2. The thermally insulating direction of boreholes according to claim 1, characterized in that polyurethane foam and / or mineral wool is used as the heat-insulating material. 3. The heat-insulating direction of the boreholes according to claim 1, characterized in that the heat-insulating material in the cavity between the shell and the connected internal pipes is two heat-insulating halves - shells.

Description

The proposed utility model “Thermal insulating direction of a borehole” refers to the oil and gas industry, in particular when drilling wells in areas of permafrost to prevent their thawing.

Known thermally insulated pipe string (see Patent for the invention of the Russian Federation No. 2197594, IPC ЕВВ 17/01, publ. 11/07/2000), including concentrically arranged sections of external pipes with a connection unit and sections of internal pipes, in an annular space between which are placed heat-insulating and shielding materials, expansion joints, made in the form of a loop-shaped bracket with cylindrical shells and placed at the joints of the column sections at the level of the connecting nodes, elastic rings installed between adjacent sections and pipes in the node of their connection, and expansion joints for thermal expansion are located at one end of the inner pipe and are rigidly connected by one cylindrical end of the shell to the outer surface of the inner pipe, and the other cylindrical end of the shell is mounted slide-movably on the inner pipe and rigidly connected to the inner surface of the outer pipes, the bending radii of the expansion joint equal to one third of the annulus, and the distance between the inner walls of the base eobraznoy staples equal h = 2 / 3R, where h - the distance between the inner walls of the base loop staples mm; R is the bending radius of the bracket, mm

A disadvantage of the known design of thermally insulated pipes is the difficulty of manufacturing, increased weight and limitation of the depth of descent, due to the fact that thermal insulation and thermal protection of the direction of the borehole at great depths are not provided.

This disadvantage is due to the peculiarities of pipe insulation, which has low heat-insulating characteristics.

A steel thermally insulated pipe is also known, the heat-insulating coating of which is made in the form of a composition based on epoxy resins with the inclusion of glass microspheres in an amount of 60% of the volume and a thickness of 4 mm, and a protective layer is placed on the heat-insulating coating in the form of a reflective screen made of aluminum foil , (see RF patent for utility model No. 62643, CL ЕВВ 17/00, 04/27/2007).

The disadvantages of the design of this pipe are relatively high heat loss.

These disadvantages are due to the design features of the known pipe, namely, frequent damage to the reflective screen during transportation and installation.

Of the known closest to the claimed one is the heat-insulating direction adopted for the prototype (see Utility Model Patent No. 74415, IPC Е21В 36/00, published June 27, 2008), containing the inner and outer pipes and heat-insulating material placed between them, the direction being made collapsible from the upper and lower parts, in the joint zone of which the inner pipes protrude from the outer pipes and are equipped with interconnected flanges, the joint zone is covered by a shell, while the cavity between the shell and the inner pipe is filled on heat-insulating material, and on the outer pipe of the lower part, fasteners are made for temporary fixation of the ribs for support on the walls of the well during installation of the direction.

A disadvantage of the known insulating direction is the high complexity of its installation during tripping, in addition, the known insulating direction is acceptable only when drilling at shallow depths of large diameter.

This disadvantage is due to the fact that the known heat-insulating direction is installed in a cylindrical shaft, prepared only by a screw drill, and allows you to install no more than two parts of the heat-insulating direction, while installation is carried out only with a crane, in addition, the aforementioned screw drilling is unacceptable for large depths.

The objective of the claimed utility model “Thermal insulating direction of a borehole is to increase operational capabilities by setting the insulating direction when drilling a well to a greater depth when drilling using a cone bit, which will significantly reduce the time for installation (installation) of the insulating direction of a borehole while improving the reliability of connecting sections and the durability of the joints of the sections of thermally insulated pipes of the insulating direction.

The technical result of the claimed utility model “Thermal insulating direction of the borehole” is the ability to set the insulating direction when drilling the well to a great depth, reducing the time to install the insulating direction as a whole, while improving the reliability and durability of the joints of the sections of thermally insulated pipes of the insulating direction.

The technical result is achieved by the fact that the well-known heat-insulating direction of the borehole, made collapsible, each section of which contains the inner and outer pipes and the heat-insulating material placed between them, according to the utility model, that it consists of two or more sections, each of which in the joint zone, has an end of the inner pipe protruding from the outer pipe, the lower end of the inner pipe of the upper section being connected to the upper end of the inner pipe of the lower section by threads connection sleeve, wherein the joint area of the outer pipes of each section is covered by a shell, and each cavity between the shell and the pipes connected to each other by a threaded coupling of the connection is filled with heat-insulating material, polyurethane foam or mineral wool is used as heat-insulating material, and each shell is made of two heat-insulated halves - shells, rigidly interconnected, and heat-insulating material in the cavity between the shell and interconnected internal friction pipes represents two insulating half - shell.

Between the distinguishing features and the achieved technical result, there is the following causal relationship.

In contrast to the known analogues and the prototype, the implementation of the thermally insulating direction of the borehole from two or more sections, each of which, in the joint zone, has ends of the inner pipe (casing pipe) protruding from the outer pipe, in which the lower end of the upper section is connected by means of a threaded sleeve connection with the upper end of the inner pipe of the lower part of the thermally insulating direction, partially lowered into the drilled borehole, which ensures quick installation (assembly) and installation and wiring of the thermally insulating direction a large depth, in contrast to the prototype object. When installing the insulating direction, a drilling rig is used, and the well is drilled with a cone bit, which also reduces the installation time of the insulating direction, while the connection of the ends of the inner pipe through the threaded coupling of the joint ensures the reliability and durability of the joints of the joints of the sections of the insulating direction. Filling each cavity between the outer pipes and the inner pipes connected with each other with heat-insulating material, and overlapping the joint zone of the outer pipes with a shell, filling the cavity between the shell and the inner pipe with the heat-insulating material using polyurethane foam as the heat-insulating material, taking into account the fact that the heat-insulating material is in the cavity between the shell and the inner pipes connected among themselves is two heat-insulating halves - shells, interconnected, bechaykoy in combination of features reduces the proposed insulating direction boreholes installation time in the insulating direction generally well while improving reliability and durability of the joint sections of insulated pipes nodes thermally insulating direction of the borehole.

An analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed utility model “Thermal insulating direction of the borehole” made it possible to establish that the applicant did not find a source characterized by signs identical to all the essential features of the claimed technical solution. According to the information available to the applicant, the set of essential features of the claimed utility model “Thermal insulation direction of the borehole” is not known from the prior art, which allows us to conclude that the claimed utility model “Thermal insulation direction of the borehole” meets the criterion of “novelty”. The determination from the list of identified analogues of the prototype as the closest in terms of the totality of features of the analogue allows us to identify a set of significant, relative to the technical result perceived by the applicant, distinctive features in the claimed utility model “Thermal insulating direction of the borehole” set forth in the utility model formula. Therefore, the claimed utility model "Thermal insulating direction of the borehole" meets the criterion of "novelty."

To verify the compliance of the claimed utility model “Thermal insulating direction of the borehole” with the criterion of “inventive step”, the applicant conducted an additional search for known solutions to identify a set of features that match the distinctive features of the claimed utility model “Thermally insulating direction of the borehole”. The search results showed that the claimed utility model “Thermal insulating direction of the borehole” does not follow explicitly from the prior art for the specialist, since the influence of the transformations provided for by the essential features of the claimed utility model “Thermal insulating direction of boreholes” for achievement of a technical result. Therefore, the claimed utility model "Thermal insulating direction of the borehole" meets the criterion of "inventive step".

Thus, the above information indicates the fulfillment of a combination of features when using the claimed insulating utility model “Thermal insulating direction of the borehole” in the form as the claimed utility model “Thermal insulating direction of the borehole” is characterized in the formula of the utility model, i.e. the possibility of its implementation using the example of a specific implementation described in the application is confirmed. Technological methods embodying the claimed utility model “Thermal insulating direction of a borehole” during its implementation, can ensure the achievement of the technical result perceived by the applicant, namely, reducing labor intensity, while improving the reliability and durability of the joint nodes of sections of thermally insulated pipes when installing a thermally insulating direction of the borehole to great depths therefore, the claimed utility model "Thermal insulating direction of the borehole" is t criterion of "industrial applicability".

The set of essential features characterizing the essence of the claimed utility model “Thermal insulating direction of a borehole” can be repeatedly used to obtain a technical result consisting in reducing the time to install a thermally insulating direction in a borehole while at the same time it is possible to set the thermally insulating direction when drilling a well to a greater depth and increase reliability and durability of joints of sections of insulated pipes of thermally insulating direction been consistent, the claimed utility model "Thermal borehole direction" meets the criterion of "industrial applicability".

The essence of the claimed utility model "Thermal insulating direction of the borehole" is illustrated by graphic materials, on which in FIG. 1 shows a General view in section of a thermally insulating direction of a borehole, consisting of three sections.

- in FIG. 2 shows the heat-insulating direction of a borehole in a section along A-A of FIG. one;

The thermally insulating direction of the borehole, made collapsible, consists of three sections 1, 2, 3. Each of the sections 1, 2, 3 of the insulating direction contains an inner pipe 4 and an outer pipe 5. Between the pipes 4 and 5 of each section 1, 2, 3 posted insulation material 6 (polyurethane foam). The thermally insulating direction of the borehole may consist of two sections 1 and 2 or three sections 1, 2, 3, as in this particular embodiment, or more sections. Each of the sections 1, 2 and 3 in the joint zone 7 has the lower ends 8 of the inner pipe 4 protruding from the outer pipe 5. The lower ends 8 of the inner pipe 4, containing the nipple part 9 in section 2, are connected by means of a threaded coupling of the connection 10 to the upper ends 11 the inner pipe 4, the lower section 1, which improves the reliability and durability of the joints of the sections of the insulating direction. Each cavity 12 in the joint zone 13 of sections 1 and 2 between the outer pipes 5 and the interconnected inner pipes 4 is filled with heat-insulating material 6, which is an installed heat-insulating shell made of polyurethane foam 6, blocked in the joint zone 13 by the shell 14, fixed by means of a clamp ( not shown) The lower ends 8 of the inner pipe 4 containing the nipple part 9 of section 3 are connected by means of a threaded coupling of the connection 10 to the upper ends 11 of the inner pipe 4, the lower section 2, which ensures improving the reliability and durability of the joint sections of the insulating nodes direction. Each cavity 12 in the joint zone 13 of sections 2 and 3 between the outer pipes 5 and the interconnected inner pipes 4 is filled with heat-insulating material 6, which is an installed heat-insulating shell made of polyurethane foam 6, blocked in the joint zone 13 by the shell 14, fixed by means of a clamp ( not shown in the drawing).

The manufacture and installation of a thermally insulating direction in a borehole is as follows.

In the manufacturing process of the thermally insulating direction of boreholes, each section of the thermally insulating direction of the borehole is made directly in the factory. The installation of the heat-insulating direction is carried out using the hoisting equipment of the drilling rig, and each section of the heat-insulating direction is fixed on the rotor of the drilling rig using an elevator. After connecting the nipple part 9 of the end 8 of the inner pipe 4 of the section 2 by means of a threaded coupling of the connection 10 to the upper end 11, the inner pipe 4 of the lower section 1, the cavity 12 in the joint zone 13 of sections 1 and 2 between the outer pipes 5 and the connected inner pipes 4 are filled with a heat-insulating material 6, which is two heat-insulating shells made of polyurethane foam 6, which are overlapped in the area of the joint 13 by the shell 14, the latter is fixed by means of a clamp (or welding). Next, sections 2 and 3 of the thermal direction are similarly connected.

The cavity 12 may be in the joint zone 13 of the docked sections may be filled with glass wool. In each section of the thermally insulating direction made directly in the factory, glass wool can be used as a heat-insulating material.

The application of the proposed utility model “Thermal insulating direction of the borehole” allows to increase operational capabilities, preserving the natural state of permafrost, eliminating thawing of rocks near the borehole and installing a thermally insulating direction in the borehole to a greater depth in comparison with the prototype object, significantly reducing the time during mounting a heat-insulating direction in the well while increasing reliability and durability the operation of the joints of the sections of the insulating direction.

Claims (3)

1. The thermally insulating direction of the borehole, made collapsible, each section of which contains an inner and outer pipe and a heat-insulating material placed between them, characterized in that it consists of two or more sections, each of which, in the joint zone, has protruding the outer pipe is the end of the inner pipe, the lower end of the inner pipe of the upper section being connected to the upper end of the inner pipe of the lower section by means of a threaded coupling, wherein the junction of the outer pipes of each section is per it is covered by a shell, and each cavity between the shell and connected by means of a threaded coupling of the inner pipe is filled with heat-insulating material. 2. The heat-insulating direction of the boreholes according to claim 1, characterized in that polyurethane foam and / or mineral wool is used as the heat-insulating material. 3. The heat-insulating direction of the boreholes according to claim 1, characterized in that the heat-insulating material in the cavity between the shell and the interconnected inner pipes is two heat-insulating halves - shells.

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