RU2272888C2 - Downhole fishing magnet - Google Patents

Abstract

FIELD: tools used during oil and gas wells to bring tool fragments, hard-alloy submagnetic drilling bit teeth and other ferromagnetic particles and objects to day surface.

SUBSTANCE: device comprises milling bit, cylindrical body with channels for well flushing formed in part of side surface and extending at an angle to fishing magnet axis. Device also has magnetic system installed on non-magnetic panel in cylindrical cavity. The magnetic system is composed of constant magnets made of rare-earth metals secured to side surfaces of ferromagnetic inserts, which form magnetic system poles. Constant magnets are arranged so that polarities thereof are oriented one towards another and the constant magnets are enclosed with C-shaped titan screens. Magnetic system pole width is not less than 1/3 of magnet width. Magnetic system and cavity are filled with filler, which provides impact resistance of the system along fishing magnet axis and prevents magnetic flux closure.

EFFECT: increased efficiency, extended service life and improved manufacturability.

3 dwg

Description

The invention relates to tools used in drilling oil and gas wells, their operation and repair for the purpose of extracting debris from a tool, hard-alloy weakly magnetic teeth of cones, shavings from drilling pipes of casing, crackers and other ferromagnetic particles and objects.

A known magnetic catcher, including a cylindrical body, a milling crown, a magnetic system installed in the body, made in the form of a radially magnetized permanent magnet fixed between concentrically located central and external magnetic circuits. The catcher has a central washing hole on the working surface (Pat. 2069737, MKI E 21 B 31/06, Decl. 12.04.94, Publ. 1996).

The drawback of such a catcher is the high accuracy requirement for the manufacture of magnetic system components, the use of a special magnet and magnetization, poor use of the working surface by the poles of the magnetic system, a large drop in the magnetic potential in the magnetic circuit and, therefore, low lifting force. The presence of a washing hole on the working surface leads to the spread of ferromagnetic particles in the face to its periphery and their separation from the working surface of the trap.

A known magnetic catcher containing a cylindrical body with an adapter and a milling crown, a magnetic system placed in the body with peripheral axial channels, including permanent magnets located between the side faces and the upper end of the central magnetic circuit and peripheral magnetic circuits of opposite polarity made in the form of glasses (Pat. 1700195 , MKI E 21 B 31/06, Declared July 31, 89, Publ. BI No. 47, 1991).

The disadvantage of this trap is the complexity of the magnetic system, the use of magnets of a special shape and their vulnerability to mechanical and chemical influences, the long path of the magnetic flux through the magnetic circuit and, as a result, a large drop in magnetic potential, which reduces the lifting force of the trap. In addition, the magnetic system is difficult to assemble and requires high precision manufacturing. Due to the small area of the central magnetic circuit, it saturates and decreases the magnetic flux density, which also reduces the lifting force of the trap. The presence of washing channels at the periphery of the magnetic system makes it difficult to capture ferromagnetic particles in the face and leads to their separation from the working surface of the trap.

The closest in technical essence and the achieved result to the proposed technical solution is a magnetic catcher, comprising a housing and a magnetic assembly installed therein in the form of magnetic cores of opposite polarity and one or more permanent magnets placed between them, magnetized in the direction of the longitudinal axis of the housing and included in the magnetic circuit in parallel (Pat. 2094589, MKI: E 21 B 31/06, Decl. 21.06.94, Publ. 1997).

The disadvantages of this catcher are the small induction of the magnetic field at the poles located above the magnets, and the large at the poles between the magnets and the yoke of the main magnetic circuit. In addition, a large induction in the main magnetic circuit and a large path of magnetic flux closure along it lead to a large drop in the magnetic potential. All of the above leads to a decrease in traction of the catcher. The area of the working surface of the trap is also used extremely inefficiently, and the presence of washing channels on the working surface makes it difficult to capture ferromagnetic particles in the face and contributes to their separation from the magnetic system. The catcher’s magnetic system is difficult to assemble.

The technical result of the invention is to increase the specific traction per unit of the working surface of the trap, the range of operating temperatures, as well as the life of the trap, reducing the consumption of permanent magnets used in the construction, improving the overall dimensions and corrosion resistance, increasing the manufacturability of the components and the assembly of the product as a whole.

The specified technical result is achieved in that in a magnetic catcher, including a milling crown, a cylindrical body with holes for washing channels located on a part of the side surface at an angle relative to the axis of the catcher, a magnetic system mounted on a non-magnetic plate in a cylindrical cavity from the working side of the catcher of permanent magnets of rare-earth metals mounted on the side surfaces of ferromagnetic inserts forming the poles of the magnetic system, permanent magnets They are located opposite each other in polarity to ensure an increase in the density of magnetic fluxes and are closed by staple-shaped titanium screens, and the width of the poles of the magnetic system has at least one third more than the width of the magnets, while the magnetic system in the cavity is filled with filler, providing impact strength of the magnetic system along the axis the catcher and the exclusion of the closure of the magnetic flux of the magnetic system from the non-working side through the body of the catcher.

The invention is illustrated by drawings, where figure 1 shows a General view of a downhole magnetic catcher; figure 2 is a cross-section of the housing along the axis of the washing channel perpendicular to the axis of the trap; figure 3 is a view of the catcher from the side of the magnetic system.

The downhole magnetic catcher comprises a cylindrical body 1 with a tapered thread 2 in the upper part of the body for connection to a drill pipe string, on the side surface of which there are holes for the flushing channels 3, as well as a milling crown 4, the magnetic system 5. The flushing fluid is supplied through the drill pipe string into the chamber 6 and through the channels 3 enters the near-hole space of the well. Channels 3 are located at an angle to the axis of the catcher in the direction of the bottom, and their outlet openings are located on part of the side surface of the housing, for example, on one third of its circumference. On the working side of the trap there is a cylindrical cavity 7 with a seat 8, above which there is a cavity 9 filled with filler, which provides impact strength of the magnetic system along the axis of the trap, designed to prevent shorting of the magnetic flux of the magnetic system from the non-working side through the trap body.

The magnetic system 5 is located on the non-magnetic plate 10. For its assembly on the plate 10, the poles 11 of the magnetic system are attached, to which the permanent magnets 12 are mounted with the opposite direction of magnetic fluxes, which allows to increase the magnetic field induction in the poles 11 of the magnetic system, and the size of the poles 11 of the magnetic systems are larger than the size of the magnetic system by no less than one third. After assembly, the magnetic system is installed in the cavity 7 on the seat 8. Brackets 13 are put on the magnets and the whole structure is filled with high-temperature filler 14, which provides impact strength of the magnetic system along the axis of the trap and eliminates the short circuit of the magnetic flux of the magnetic system from the non-working side through the trap body.

As a high-temperature filler (compound) can be used, for example, universal epoxy adhesive brand EDP, TU 2252-001-56793573-2001. Its working temperature in the solid state is up to 120 degrees. Celsius. In the initial state, it is a viscous liquid substance, after hardening with the help of the hardener included in the kit, it becomes glass-like, but resistant to shock loads.

Can also be used, for example, epoxy vinyl ester resin type HETRON 922 with a hardener (accelerator) type NL-23. The operating temperature in the solid state is up to 250 degrees. Celsius. In the initial state, also a viscous liquid substance after hardening becomes glass-like, but resistant to shock loads in the bottom of the well.

Before use, fillers are preheated in a water bath (about 100 degrees) to increase fluidity. When filling cavities, a non-magnetic filler is additionally used: for operating temperatures up to 120 degrees. - cotton threads, aluminum, copper shavings or wire chippings, etc. At temperatures up to 250 degrees. metal non-magnetic filler can be used. The filler increases the strength of the compound.

After assembly, the working surface 15 of the catcher is ground. Downhole magnetic catcher operates as follows. Using a taper lock thread 2, the catcher is connected to the drill pipe string. During the descent of the trap into the well through the hole in the drill pipe, flushing fluid is supplied. When the bottom of the well is reached, the column is rotated, the flushing fluid cleans foreign particles from small particles of rocks, and the teeth of the milling crown, loosening the bottom, simultaneously move the foreign ferromagnetic objects to the center of the bottom, facilitating their capture by the magnetic field of the catcher. Since the density of the magnetic flux of the catcher is high, there is a reliable capture of ferromagnetic objects, including weakly magnetic, such as cone teeth. After raising the catcher from the well, the milling crown is turned away and the working surface of the catcher is cleaned of trapped ferromagnetic objects. After the described operations, the catcher is again ready for descent into the well.

A significant increase in the specific pulling force per unit of the working surface of the catcher is achieved through the use of permanent magnets, for example, from rare-earth metals, in the design of the magnetic system, and their inclusion against the side surfaces of the poles, which makes it possible to compress the magnetic flux and significantly increase the magnetic field induction. And also due to the rational design of the magnetic system, which allows minimizing the closure of the magnetic flux and thereby reducing the drop in magnetic potential at the poles. The latter allows you to use the energy of permanent magnets mainly to produce useful work, that is, to capture ferromagnetic particles in the bottom of the well. The use of cobalt steel or chemically pure iron poles as a material makes it possible to at least double the specific traction force of a catcher.

Reducing the consumption of permanent magnets used in the design is achieved due to the rational height of the magnetic system, as well as the rational thickness of the layers of magnets.

Improving the overall dimensions is achieved due to the rational dimensions of the magnetic system and the well flushing system used.

The increase in operational efficiency is achieved by a significant increase in the continuous operation of the trap to completely clean the well in comparison with previously known designs of traps, a polished working surface greatly facilitates the removal of ferromagnetic particles after lifting the trap. The catcher has a small weight and height, which is achieved due to the small volume of the magnetic system and the location of the washing holes.

An increase in the service life of catchers (more than five years) is achieved due to the strength and energy characteristics of permanent magnets made of rare-earth metals, the spatial separation of the magnetic system and the washing system.

An increase in the operating temperature range was made possible due to the high limit operating temperature of the magnets to 200 ° C without reducing their characteristics and parameters, as well as the compound used with the operating temperature also up to 200 degrees Celsius.

Improving corrosion resistance is achieved through the use of various types of coatings, namely blackening, anodizing, chromium plating of catcher structures.

The manufacturability of the manufacture and assembly of individual components of the catcher, as well as the product as a whole, is ensured by the simplicity of the design of the body and elements of the magnetic system, which do not require high manufacturing accuracy and special adjustment. The manufacture of layers of magnets is not a monolith, but of individual magnets greatly facilitates the assembly of this element of the magnetic system, since it does not require overcoming large forces of magnetic traction. The removable crown allows quick replacement in case of wear.

The borehole magnetic catcher of the proposed design allows to increase the specific pulling force per unit of the working surface of the catcher, the range of operating temperatures, as well as the service life of the catcher, to reduce the consumption of permanent magnets used in the design, to improve the overall dimensions and corrosion resistance, to increase the manufacturability of assemblies and assembly of the product as a whole .

Claims (1)

A downhole magnetic catcher, including a milling crown, a cylindrical body with channel openings for flushing a well on a part of the side surface at an angle relative to the axis of the catcher, a magnetic system mounted on a non-magnetic plate in the cylindrical cavity from the working side of the catcher, mounted on rare-earth permanent magnets mounted on the lateral surfaces of the ferromagnetic inserts forming the poles of the magnetic system, the permanent magnets are arranged opposite each other in polarity to ensure The increase in the density of magnetic fluxes is covered by bracket-shaped titanium screens, and the width of the poles of the magnetic system has at least one third more than the width of the magnets, while the magnetic system and the cavity are filled with filler, providing impact strength of the magnetic system along the axis of the trap and eliminating the closure of the magnetic flux of the magnetic system on the non-working side through the body of the catcher.

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