RU1790658C - Diamond drill bit - Google Patents

Abstract

Usage: drilling exploration wells. The crown includes a housing 1, the outer side surface 2 of which is made in the form of a polyhedron in cross section, the inner 3 has a circle profile 5 of the polygonal outer section of the housing 1. The front portion 6 of the longitudinal cutting edge 7 of the sector of the matrix 4 is made tapering relative to the faces and circular section of the housing and transverse 8 are perpendicular to the faces of the polygonal section. 1 s.p. f-ly, 3 ill.

Description

FIELD OF THE INVENTION The invention relates to the destruction of rocks, namely the drilling of exploratory wells.

Drill bits are known that include a housing and reinforced with rock cutting elements of the matrix sector, rigidly fixed to the housing.

A drawback of this drill bit is that when drilling the matrix sectors, they experience a load directed tangentially to the perimeter of the matrix sector and, in general, to the perimeter of the body. At the same time, for the matrix sector on the side surface of the housing there are practically no supporting surfaces that would transfer the load to the matrix sectors during drilling onto the crown body. As a result of this, the sector of the matrix, in addition to destroying the rock, must experience and perceive virtually the entire load that causes the sector to overstrain, causing its premature destruction. The exit of the matrix sector from the system is largely due to the fact that its rigidity. The fastening to the body largely rests on the weld layer, while for more monolithic fastening to each other it would be advisable to have a support on the matrix sector on the side surface of the body, which allowed decompose the tangential forces into a couple of forces, one of which would be well perceived by the body of the drill bit. Thus, the lack of support of the matrix sector against the housing is the reason for the occurrence of vibrations manifested during drilling due to the lack of solidity in the load perception by the matrix sector and the housing of the drill bit. This is the reason for premature aging and exit from drill string as a crown assembly that must actively drill the rock.

A diamond impregnated tool is known, consisting of a body and divided by washing grooves-channels into separate sectors of the matrix containing diamonds, carbide frame and wear-resistant material, and the sectors of the matrix are welded from the end to the body of the

ronchi.

The disadvantage of this diamond impregnated tool is that in fact such sectors of the matrix are fully stressed when drilling themselves due to their lack of support on the body. This load is not transferred to the housing, since it is created by tangential forces, which generate oscillations in the sector of the matrix in the same way as they arise in a tuning fork. This is the main reason for

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the cause of premature failure of the drill bit, blunting the tool, inefficient cutting. In other words, the load, which as a whole must be borne by the entire crown, in reality, only the sectors of the matrix perceive. In this case, the drill bit body works by itself. All this is due to the fact that the matrix sector does not have support on the side surface of the housing. The rigidity of fastening the matrix sector to the housing is based on the soldering of the matrix sector to the housing. This mode of loading the sector of the matrix with an unusual functional task for it leads to the failure of the tool that has not worked out its resource. From the point of view of increasing the reliability and durability of the tool, it is necessary that the matrix sectors together with the body work as one piece, since only in this case it can be decomposed into components, one of which will be perceived by the body of the drill bit. This device is adopted as a prototype .

An object of the invention is to increase drilling efficiency.

This goal is achieved in that the diamond drill bit includes a housing, the inner side surface of which has a circle profile in cross section, and matrix sectors are located from the working end of the housing, the outer side surface of the housing has a polygon profile in cross section, at the corners of which vertices are located sector of the matrix, while the front nasal part of the longitudinal edge of the sector of the matrix is made tapering relative to the faces and a circular cross section of the inner side surface of the housing.

Compared to the drill bit of the prototype and other known solutions, new features of the claimed invention are the cross section of the outer side surface of the body in the form of a polygon profile, which allows each matrix sector to abut a pad on the side surface of the body, which allows drilling, to transfer part of the effort exerted during drilling to the body of the drill bit, thereby ensuring that the load is monolithic by the sector of the matrix and the body; the implementation of the front nose of the longitudinal sector of the matrix tapering relative to the faces and a circular cross-section of the inner side surface of the housing, which allows, in comparison with the prototype, to reduce the consumption of scarce material of the matrix sector, on the one hand, and on the other, to ensure drilling efficiency due to the smooth entry of the matrix sector into the body destructible rock. At the same time, an increase in the live section of the washing channel occurs, which leads to an increase in the removal of the destroyed rock from the drilling zone due to a decrease in the hydraulic resistance of the washing channel. In addition, fixing the sector of the matrix at the top of the polygon of the housing around the entire perimeter of its outer side surface, on the one hand, increases the rigidity of fixing each sector of the matrix to the body of the diamond drill bit, and on the other hand, due to the presence of the supporting surface on the side surface of the body, decomposition of the tangential load arising during drilling, acting on the sectors of the matrix into two components, one of which is perceived by the body of the drill bit. This unloads each sector of the matrix. This ultimately leads to increased reliability, durability and life of the drill bit. This simultaneously reduces the metal consumption for the manufacture of the body of the drill bit, composite matrix material, reduces vibration, energy consumption, increases the efficiency of drilling in fractured rocks.

Figure 1 presents a General view in a perspective view; figure 2 - axonometric view of the working end of the housing; Fig. 3 is a top view of a diamond drill bit.

The claimed diamond drill bit includes a housing 1, the outer side surface 2 of which is in cross section made in the form of a polyhedron, and the inner 3 has a cross section in profile of a circle. The diamond drill bit contains from the working end of the housing 1 of the matrix sector 4 in the corners 5 of the outer polygonal section of the housing 1. In this case, the front part 6 of the longitudinal cutting edge 7 of the matrix sector 4 is made tapering relative to the faces and the circular section of the inner side 3 of the surface of the housing 1, and the rear transverse 8 are perpendicular to the faces of the polygonal cross-section of the housing 1. This design of the diamond drill bit allows to reduce the material consumption for the manufacture of the housing 1, sectors of the matrix 4, creates the surface on the outer lateral side of each sector of the matrix 4, which allows part of the drilling load experienced by each sector of the matrix 4 to be redistributed onto the body 1 of the diamond drill bit, thereby creating conditions for uniform load perception during drilling by the body 1 and the sector of the matrix 4.

Diamond drill crown works as follows. When the diamond drill bit acts on the face, the nose, the narrowed front part of the matrix sector 4 interacts with the rock being destroyed. The narrowing allows the matrix sector 4 with optimal loads to penetrate into the body

D) rocks with a thin drilling ring, which further, due to the smooth narrowing of the bow of the sector of the matrix 4, gradually expands to the required thickness of the drilling ring created by the rear transverse

t-face 8 of the sector of the matrix 4. Moreover, due to the fact that the outer side surface in cross section has a polyhedron profile, and in the corners at its vertices the sectors of the matrix 4 are located, the rigidity of their fastening to the housing 1 increases, supporting surfaces are created for perception These drilling loads are generally tangential. It is the presence of a supporting surface on the housing 1 for each sector

from matrix 4 creates the conditions for decomposing the drilling load into two components, one of which is perceived by the drill bit body 1. The latter contributes to a more even load perception.

all the details of the drill bit, bringing the bit as a whole closer to a more monolithic system, and also leads to a decrease in the absolute value of the tangential forces perceived by the sectors of the matrix 4 at

with drilling, the latter increases the vibration resistance of the drill bit, the reliability and durability of its operation by reducing the load on the metal bond of the sector of the matrix 4 to the housing 1 of the drill bit. All these advantages are associated with the arrangement of the sectors of the matrix 4 along the perimeter of the working end of the housing at angles 5 at the vertices of the polygonal profile of the outer side surface of the housing 1.

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Technical appraisal and economic benefits

The claimed diamond drill bit as compared with the prototype and other known solutions are as follows. n The material consumption is reduced in the manufacture of the housing 1 and the sectors of the matrix 4, which reduces the weight characteristics of the drill bit due to the cross-section of the housing 1 in the form of a polyhedron profile, as well as the implementation of the front nose 6 of the sector of the matrix 4 tapering.

The rigidity increases. And the vibration resistance of fixing the sectors of the matrix 4 to the housing 1 due to the fact that their angular arrangement in the corners 5 at the vertices of the polygon itself creates rigidity

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since the sector of the matrix 4 acts as a link in the truss, the role of which is performed by the body 1 of the drill bit. From the viewpoint of rigidity, the polyhedron of housing 1 and the sector of matrix 4 in angle 5 at its top complement each other, increasing the rigidity of the drill bit as a whole. In addition, the flaccidity profile of the lateral outer surface of the housing 1 gives each sector of the matrix 4 a support point about the housing, which leads to the decomposition of the tangential load when drilling into two components, one of which is perceived by the housing 1 of the drill bit. This means that the supporting surfaces well prepared for the perception of tangential loads during drilling.

The load on the sector of each matrix 4 is reduced due to the decomposition of the load into two components, which unloads it and

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On this basis, it increases reliability and durability, and the service life of the diamond drill bit increases.

The mechanical speed and productivity of drilling increases due to the fact that the drill bit has increased rigidity and vibration resistance, more even distribution of the load between all parts of the drill bit, smooth drilling of the rock with a gradual increase in load, which leads to sparing reliability and loads drilling mode.

The readiness of the diamond drill bit for use in the national economy is high, since all manufacturing operations are carried out according to standard technology widely used in diamond tool factories.

Claims (2)

1. A diamond drill bit, including a body, an inner side surface. Of which the cross section has a circle profile, and matrix sectors are located on the working end of the body, differing in that, in order to increase drilling efficiency, the outer side surface of the body in cross section has profile a lot a square, in the corners at the vertices of which the matrix sectors are located, while the front nose part of the longitudinal edge of the matrix sector is made tapering relative to the faces and a circular cross section of the inner side surface of the housing. 2. The diamond drill bit according to claim 1, characterized in that in the corners at the vertices of the polygon the sectors of the matrix are periodically placed through one corner. Phase 1 4 1 / h..l-4-v / -vrv, 3 ,. i ii