EA009234B1 - Rock-breaking drilling tool - Google Patents

Abstract

The invention relates to bore-hole technology.The technical result of the invention is to provide contact interaction of a double cone bore bits forming a support surface therebetween, creating pressure rises of washer fluid inside the tool, using thereof as an axial load and feeding mud flow beneath matrix sectors.The rock-breaking drilling tool comprises outer and removable inner bits, matrices casings and flushing courses, the inner part of the outer bit is designed as vertically-coaxial cones interacting with response cones of the lower part of the inner bit casing thus forming a support surface therebetween, the outer bit matrix is made staged and divided into sectors, the flushing courses of the outer bit are positioned horizontally below the matrix upper step.The inner bit casing has a longitudinal axial chamber with staged shoulders, wherein the chamber is oriented by its radial channels for corresponding upper and lower stages of the outer bit matrix.A cavity is made in the lower part of the longitudinal axial chamber transforming into the matrix with spreading therefrom flushing courses of the inner bit and passing into a concentric recess in the matrix upper part associated with the matrix lower stage slots of the outer bit.

Description

The invention relates to the technique of drilling wells and is intended for use in drilling rock cutting tool, mainly diamond.

Known plug rock-breaking tool, including outer and inner housing with slot-slot connection between them and the rock-breaking body attached to the lower part of the inner housing. Technique and technology of exploration; organization of production. WIEMS, M, 1980.

A disadvantage of the known rock cutting tool is the difficulty of bringing the tool into working condition due to the presence of a spline-groove connection in the design.

Also known is a rock drilling tool, consisting of an outer and a removable inner crown, including shells with matrices and flushing channels attached to them. USSR Author's Certificate No. 1231205, class E. 21B 10/48, 1986.

The specified tool to the technical essence is closest to the proposed invention and can be taken as a prototype.

The disadvantage of the prototype is that the form of interaction of the outer and inner crowns on a cylindrical surface does not ensure the stability of the instrument in its assembled form, difficult setting of a removable inner crown in the working position and removing it from there, which reduces the reliability of the instrument.

In addition, in this design of the tool does not provide for the accumulation of energy of the washing fluid to create an axial load and increase the intensity of destruction of rocks, an imperfect system of cooling the tool and removing sludge.

The objective of the invention is the creation of reliable in operation of the drilling rock cutting tool, allowing to increase the efficiency of the process of dredging wells.

The technical result of the invention is the contact interaction of the inner and outer crown in the form of a double cone coaxially aligned vertically with the formation of a supporting surface between them, the ability to create pressure gains of the washing liquid inside the instrument and use it as an axial load, feeding the power flow horizontally under the matrix sectors opposite direction to tool rotation.

This is achieved by the fact that in a drilling rock cutting tool containing outer and removable inner crowns, including bodies with matrices and flushing channels attached to them according to the invention, the inner part of the body of the outer crown is designed as coaxially vertical cones contacting with mating cones of the lower part of the body the inner crown with the formation of a support surface between them, and the smaller bases of the upper cones combined with the large bases of the lower cones c, the matrix of the outer crown is made stepwise with longitudinal division into sectors, the upper stage is half-grooved to the outer side, the lower stage is grooved, the flushing channels of the outer crown are horizontally located below the upper stage of the matrix and are tangentially biased to the opposite front faces of the sectors along the rotation, while the crown has a longitudinal-axial chamber with longitudinal ledges facing the inside of the chamber with lateral inclined holes, the chamber being held on each torso bordering over the ledges of radial channels is hydraulically oriented under the corresponding upper and lower stages of the matrix of the outer crown, in the upper position the radial channels are connected to an annular recess placed on the outer wall of the case of the inner crown with the ability to communicate with the flushing channels of the outer crown, in the lower position the radial channels are held having an output under the matrix sectors in the direction opposite to the rotation of the tool, in the lower part of the longitudinal-axial chamber with longitudinal ledges and facing the inside of the chamber is formed passing in the axial cavity of the die, and radiating to the periphery of the inner end face flushing channels crowns extending in concentric aperture formed in the upper part of the die slots and associated lower-stage matrix outer crown.

Distinctive features of the invention: contact conical interaction of the outer and inner crown with the formation of a supporting surface between them ensures stable operation of the assembled tool, unimpeded positioning and removal of the removable inner crown, as well as the creation of a differential pressure of flushing fluid in the longitudinal axial chamber with multi-level ledges and its application through the ledges into the matrix of the inner crown and through the supporting one awn matrix in a stepped outer crown formation is achieved and transmission of axial load in the area immediately uglubki wells decreases the magnitude than mechanical axial load transmitted from the earth's surface, its loss during transmission, power consumption is reduced drilling process.

The flow of flush fluid from the longitudinal-axial chamber with long-staggered benches facing the inside of the chamber through radial channels, which are bordered above the ledges in each tier under the corresponding upper and lower stages of the outer crown matrix, in the upper position are connected to the annular recess, placed on the outer wall of the case of the inner crown with the possibility of communication with the washing channels outside

- 1 009234 crowns horizontally under the opposite front edges of the matrix sectors, in the lower position the radial channels are made to exit under the matrix sectors, in the direction opposite to the tool rotation, an increase in the depth of the rock failure zone is achieved, the contact specific load between it and the tool matrix decreases, contact counter velocity between the sectors of the matrix and the power flow of the washing liquid, which, along with volumetric washing upwards, increases the rate of cooling and removal of the washings sludge from the sectors of the stepped matrix of the outer crown, which increases the efficiency of the dredging process.

By dividing the upper stage of the outer crown matrix into sectors by half-grooves to the outer side, the lower stage by grooves, the efficiency of supplying the power flow of the drilling fluid and removal of sludge from the tool during the drilling process increases.

Performing in the lower part of the longitudinal-axial chamber with multi-level ledges facing the inside of the chamber passing into the axial cavity of the matrix, with internal crown washing channels diverging from the periphery at the end of the crown, passing into a concentric opening in the upper part of the matrix steps of the matrix of the outer crown; a hydraulic system is created for the destruction of the rock, cooling and removal of sludge from under the end of the inner crown.

FIG. 1 shows a general view of a rock drilling tool; FIG. 2 is a section through ΛΑ in FIG. 1, in FIG. 3 is a section along BB in FIG. 1 and in FIG. 4 view from the end of the matrix.

Drilling rock cutting tool consists of an outer crown, comprising a housing 1 with an annular recess 2, in the upper part the housing 1 is connected to an adapter 3, the lower end of which has projections 4 that are diametrically opposed. A stage matrix is attached to the housing 1 consisting of the upper 5 and lower 6 steps, while the upper step 5 is longitudinally divided into sectors 7 by semi-cavities to the outer side 8, lower stage 6 by sectors 9 by grooves 10. The flushing channels 11 of the outer crown are horizontally located below the upper stage 5 matrices and tangentially derived under the counter front edges of the sectors 7 in the direction of rotation. The inner part of the housing 1 is made in the form of vertically coaxial cones 12 and 13, which interact in contact with the formation of a supporting surface between them 14 with counter-cones of the lower part of the body 15 of the inner crown, and the smaller bases of the upper cones 12 are combined with the larger bases of the lower cones 13. К matrix 15 is attached to the housing 15 and the housing 15 has a longitudinal-axial chamber with longitudinal ledges facing the inside of the chamber 17 with lateral inclined openings 18, the chamber 17 being each tier is boundary over the ledges 19 and 20 of the radial channels, respectively, 21 and 22 are hydraulically oriented under the corresponding upper 5 and lower 6 steps of the matrix of the outer crown, in the upper position, the radial channels 21 are connected with an annular recess 23 placed on the outer wall of the body 15 of the inner crown , with the possibility of communication with the washing channels 11 of the outer crown, in the lower position, the radial channels 22 are made to exit under the sector 9 of the matrix in the direction opposite to the rotation of the tool. In the lower part of the longitudinal-axial chamber 17, the matrix 16, which passes into the axial cavity 24, is formed, with diverging channels 25 of the inner crown extending from the periphery along the end, into the concentric opening 26, made in the upper part of the matrix 16 and connected to the slots 10 of the lower stage 6 matrix outer crown.

The housing 15 is also provided with a locking mechanism consisting of a head 27 with holes 28, a return sleeve 29, a spring 30 and stoppers 31.

Drilling rock cutting tool works as follows.

Initially, the crown 1 of the outer crown connected to the adapter 3 and attached to it with a step matrix consisting of the upper 5 and lower 6 steps is lowered into the well on the drill (casing) pipes (not shown). After that, the inner cavity of the drilling (casing) pipes under the action of its own weight or the action of the downward flow of the washing liquid lower the body 15 of the inner crown with the matrix 16 attached to it. When aligning the vertical coaxial cones 12 and 13 of the outer crown body with counter cones of the inner crown body , the latter rests on the bearing surface 14, and the stopper 31 expandable by the springs 30 fall into the annular recess 2 of the adapter 3, and the drilling rock-destroying tool will occupy the working position in the assembly this form.

At the beginning of the drilling process from the adapter 3 rotation and axial load through the housing 1 is transmitted to a stepped matrix consisting of the upper 5 and lower 6 stages, at the same time, the rotation from the adapter 3 through the projections 4 is transmitted and the stoppers 31 interacting with them, which ensures synchronous rotation of the outer and inner crowns. Simultaneously with the transfer of rotation, the washing fluid is also supplied, which flowing through the holes 28, heads 27 and lateral inclined holes 18, in the longitudinal-axial chamber 17 creates an increase in pressure drop and interacting with ledges 19 and 20 create an axial load on the matrix 16 of the inner crown through the bearing surface 14 on the stepped matrix of the outer crown, while maintaining the working position of the tool. When this formed in the longitudinal-axial chamber 17 of the power flow of the washing fluid is divided into three streams, the first through the radial channels 21, the annular recess 23 and the flushing channels

- 2 009234 falls under the front edges of sectors 7, removing sludge through semi-cavities 8, the second through radial channels 22 is fed in the direction opposite to rotation under sectors 9 of the lower stage 6 of the matrix, the third flowing through the axial cavity 24 and the washing channels 25 of the inner crown, destroys the rock and cooling the matrix 16 carries the slurry through a concentric opening 26 connected with the slots 10 of the lower stage 6 of the matrix.

If it is necessary to remove the inner crown, the catcher is lowered on a rope (not shown in the drawing) that grabs the head 27 and pulls up, the return sleeve 29 moves along the body 15 and shifts the stoppers 31 into the body, the latter is released and removed to the surface.

The proposed solution allows you to create reliable in operation of the drilling rock cutting tool and improve the efficiency of the process of dredging wells.

Claims (1)

CLAIM Drilling rock cutting tool containing outer and removable internal crowns, including cases with matrices and flushing channels attached to them, characterized in that the inner part of the outer crown body is made in the form of cones coaxially vertically and interacting with response cones of the lower part of the inner crown with the formation of a supporting surface between them, and the aggregately smaller bases of the upper cones are combined with the large bases of the lower cones, the matrix of the outer crown made stepwise with longitudinal division into sectors, the upper step half-grooved to the outer side, the lower step grooves, the flushing channels of the outer crown are horizontally located below the upper step of the matrix and tangentially brought under the counter front edges of the sectors in the direction of rotation, while the body of the inner crown has a longitudinal-axial a chamber with multi-level ledges facing the inside of the chamber with lateral oblique apertures, the chamber being held on each tier, bordering on the ledges radial channels are hydraulically oriented under the corresponding upper and lower stages of the matrix of the outer crown; in the upper position, the radial channels are connected to an annular recess placed on the outer wall of the inner crown body with the ability to communicate with the flushing channels of the outer crown; matrix in the direction opposite to the rotation of the tool, in the lower part of the longitudinal-axial chamber with long benches facing inward measures, passing into the axial cavity of the matrix, with diverging from it to the periphery at the end of the washing channels of the inner crown, passing into a concentric opening, made in the upper part of the matrix and connected with the grooves of the lower stage of the matrix of the outer crown.