RU2445438C2 - Diamond drill bit - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: diamond drill bit comprises a body and a diamond-containing matrix with impregnated three-staged and reaming layers, collars at the end and flushing windows in each stage of the impregnated layer communicating with the side external and internal cylindrical channels. Rational diameter of a single-point diamond in each stage of the impregnated layer of the matrix is determined by rated relation depending on physical and mechanical properties of drilled rocks. Besides, along the external and internal side parts of the matrix the gaps between diamonds of the reaming layer are evenly reinforced with particles of superhard nanomaterial, linear dimensions of which make 50÷150 nanometres, and side external and internal cylindrical channels of the drill bit at least in the first stage of the impregnated layer of the matrix, communicate with each other by additional channels, width of which makes (0.6÷0.8) of the cylindrical channel diameter, and the depth is equal to the height of the matrix collar.

EFFECT: improved operational resistance of the diamond drill bit and mechanical speed of drilling.

2 cl, 2 dwg

Description

The invention relates to drilling equipment and is intended for use as diamond crowns and bits reinforced with synthetic and natural diamonds, or superhard materials for drilling wells.

Known diamond drill bit, comprising a housing and a diamond-containing matrix with impregnated and scoring layers, ridges at the end and flushing windows (see US patent No. 3106973, 175-413, priority from 09/26/1960).

The disadvantages of this crown are the relatively small height of the impregnated layer and the irrational size of the diamond grains in it, the imperfect design of the undercut layer of the matrix and the underdeveloped geometry of the flushing system of the crown. This leads to a decrease in the mechanical drilling speed of the crown and its premature decommissioning.

A diamond drill bit is also known, including a housing and a diamond-containing matrix with impregnated and scoring layers, flanges at the end and flushing windows communicating with the lateral outer and inner cylindrical channels, in which the disadvantages of the aforementioned crown are partially eliminated (see ed. St. RF No. 1609939 )

The disadvantages of this crown are the frequent polishing of diamond grains of the working end, the low height of the impregnated layer, increased wear on the outer and inner diameters of the crown, and irrational geometry of the flushing system. Specified reduces the performance of these diamond crowns during drilling.

The closest analogue to the claimed solution is the diamond drill bit described in the BOART LONGYEAR catalog (see Appendix 1), which includes a body and a diamond-containing matrix with impregnated and scoring layers, with ridges at the end and flushing windows in each stage of the impregnated layer communicating with the side external and internal cylindrical channels.

The disadvantages of this crown are the irrational size of diamond grains in the steps of the impregnated matrix layer, increased wear on the outer and inner diameters of the crown, and the non-optimal geometry of the flushing system. This leads to polishing diamonds at the end of the matrix, reducing the operational stability of diamond crowns and the mechanical drilling speed with them.

The technical solution is aimed at increasing the operational stability of the diamond core and the mechanical drilling speed by choosing the rational size of the diamond grains of the impregnated matrix layer, taking into account the physicomechanical properties and elastic constants of drillable rocks, using an undercut layer of reinforcement with superhard nanomaterial particles in the matrix between diamonds, and optimizing geometric parameters flushing system.

In the proposed diamond drill bit, comprising a housing and a diamond-containing matrix with impregnated three-stage and undercut layers, flanges at the end and flushing windows in each stage of the impregnated layer communicating with the lateral external and internal cylindrical channels, the diameter of the diamond grain in each stage of the impregnated matrix layer is determined by addictions

where d is the diameter of the diamond grain;

α is the coefficient of proportionality (α = 1,0 ÷ 1,1);

In ₁ - a constant, depending on the fracture toughness, is determined by the method of O.N. Grigoriev;

In ₂ - the elastic constant of the rock;

,

,

where n is the Poisson's ratio;

E is the elastic modulus of the rock;

K is the elastic constant of the rock;

K = 9 (1-n) / 16,

where n is the Poisson's ratio;

c - coefficient taking into account the increase in the bearing strength of the contact of diamond with rock, is determined by the method of A.Yu. Ishlinsky;

ρ ₀ - yield strength of the rock,

in addition, on the outer and inner side parts of the matrix, the gaps between the diamonds of the cutting layer are evenly reinforced with particles of superhard nanomaterial, the linear dimensions of which are 50 ÷ 150 nanometers, and the lateral outer and inner cylindrical channels of the crown, at least in the first stage of the impregnated matrix layer, additional channels communicate with each other, the width of which is (0.6 ÷ 0.8) the diameter of the cylindrical channel, and the depth is equal to the height of the ridge of the matrix.

Due to the fact that the diameter of the diamond grain in each step of the impregnated matrix layer is determined by the dependence

where d is the diameter of the diamond grain;

α is the coefficient of proportionality (α = 1,0 ÷ 1,1);

In ₁ - a constant, depending on the fracture toughness, is determined by the method of O.N. Grigoriev;

In ₂ - the elastic constant of the rock;

,

,

where n is the Poisson's ratio;

E is the elastic modulus of the rock;

K is the elastic constant of the rock;

K = 9 (1-n) / 16;

where n is the Poisson's ratio:

c - coefficient taking into account the increase in the bearing strength of the contact of diamond with rock, is determined by the method of A.Yu. Ishlinsky;

ρ ₀ - yield strength of the rock,

the critical size of the diamond grain is established, at which, when it is introduced into solid rock, a transition occurs from its completely elastic destruction to its elastoplastic. With this deformation of the rock, diamond grains act on it mainly in the tangential direction, in which the shift and detachment of the rock particles occurs in the direction of its least resistance. For this reason, the possibility of polishing diamond grains and stopping the wellbore for sharpening polished diamond grains is reduced, which leads to an increase in drilling productivity.

Studies conducted at Tula NIGP established the expression for the force that causes plastic flow during the introduction of diamond grains into the rock (see Budyukov Yu.E., Vlasyuk V.I., Spirin V.I. Diamond rock-cutting tool. - Tula: IPP “Grif and K”, 2005. - 288 p.).

where P _T is the force causing plastic deformation;

p _o - yield strength of the rock;

c - coefficient taking into account the increase in the bearing strength of the contact of diamond with rock, is determined by the method of A.I. Inshlinsky;

To, In ₂ - elastic constants;

where n is the Poisson's ratio;

a is the coefficient of proportionality;

r is the critical radius of the indenter;

E is the elastic modulus of the rock.

The critical radius of the indenter during the transition from elastic to plastic deformation is determined according to the law of F. Auerbach

where P _c is the critical load, n;

In ₁ - a constant, depending on the fracture toughness, is determined by the method of O.N. Grigoriev;

n ₁ is a constant (n ₁ = 1).

Equating P _c and P _T and performing the transformations, we obtain an expression for determining the diameter of the diamond grain

where d is the diameter of the diamond grain.

Thus, there are critical sizes of diamond grains (diameters) at which there is a transition from completely elastic fracture of the rock to its elastic-plastic fracture.

Due to the fact that on the outer and inner side parts of the matrix, the gaps between the diamonds of the undercut layer are evenly reinforced with particles of superhard nanomaterial, the linear dimensions of which are 50 ÷ 150 nanometers, the wear resistance of the undercut layer of the matrix is significantly increased, and therefore, the wear of the crown on the outer and inner diameters decreases drilling. When using particles of superhard nanomaterial (for example, nanopowders of boron nitride, diamond, etc.) with a size of less than 50 nanometers, a decrease in the wear resistance of the matrix undercut is observed, and when the particle sizes of the superhard nanomaterial increase to more than 150 nanometers, an increase in the wear resistance of the matrix undercut is not observed.

Due to the fact that the lateral outer and inner cylindrical channels of the crown, at least in the first stage of the impregnated matrix layer, communicate with each other additional channels, the width of which is (0.6 ÷ 0.8) of the diameter of the cylindrical channel, and the depth is equal to the height of the matrix , the conditions for the removal of particles of drilled rock from the bottom of the well are improved due to the possibility of its transportation through additional channels into the annulus and further to the day surface.

When the width of the additional channel is less than 0.6 of the diameter of the cylindrical channel, there is an increase in wear of the impregnated layer of the crown, and with an increase in the width of the additional channel to more than 0.8 of the diameter of the cylindrical channel, the decrease in wear of the impregnated layer is not observed.

All this leads to an increase in the mechanical drilling speed and operational stability of the crown.

The diamond drill bit is shown in figures 1 and 2, where figure 1 is a General view of the crown, and figure 2 is a diagram of the placement of diamond grains and particles of superhard nanomaterial in the matrix of the crown.

The diamond drill bit consists of a housing 1, a diamond-containing matrix 2 with steps of impregnated layer a, b, c, ridges 3 of height h, flushing windows 4 in each step of the impregnated layer communicating with the side inner cylindrical channels 5 and outer cylindrical channels 6, and additional channels 7. In the diamond-containing part of the matrix 2 there are diamonds 8 of the impregnated layer, diamonds 9 of the undercut layer and particles 10 of superhard nanomaterial.

A diamond drill bit works as follows: when creating axial and circumferential forces, the rock is effectively destroyed by a diamond bit due to the fact that the size of the diamonds of the impregnated layer is selected according to the calculated dependence (5) and corresponds to the physicomechanical properties of drill rocks, which excludes polishing of the working face diamonds .

In this case, the washing liquid inside the housing 1 passes, touching the matrix 2, through the lateral internal cylindrical channels 5, the washing windows 4, additional channels 7 and washes the matrix 2 with ridges 3 from the end and sides, then through the outer cylindrical channels 6 completely removes the destroyed rock particles from the face, including large ones, which excludes the possibility of secondary grinding them. In this case, the diamond drill bit is not subjected to increased wear by abrasive drill cuttings in the outer and inner diameters, since in the matrix the gaps between the diamonds of the cutting layer are uniformly reinforced with particles of superhard nanomaterial. After working out the steps a of the matrix, the steps in c are worked out.

Thanks to this embodiment of the diamond drill bit, the axial and circumferential forces transmitted to it provide for the effective destruction of the rock and the removal of its particles with the least wear on the working part of the crown.

The technical and economic efficiency of the proposed technical solution is to increase the operational stability and mechanical speed of drilling rocks.

The economic effect on one diamond crown with a diameter of 93 mm is 9000.0 rubles.

Claims (2)

1. Diamond drill bit, comprising a housing and a diamond-containing matrix with impregnated three-stage and scoring layers, ridges at the end and flushing windows in each stage of the impregnated layer, communicating with the lateral outer and inner cylindrical channels, characterized in that the diameter of the diamond grain in each stage of the impregnated matrix layer is determined by the dependence

where α is the coefficient of proportionality (α = 1.0 ÷ 1.1);
B ₁ - a constant depending on the fracture toughness, is determined by the method of O.N. Grigoriev;
In ₂ - the elastic constant of the rock;

where n is the Poisson's ratio;
E is the elastic modulus of the rock;
K is the elastic constant of the rock;
K = 9 (1-n) / 16,
where n is the Poisson's ratio;
c - coefficient taking into account the increase in the bearing strength of the contact of diamond with rock, is determined by the method of A.Yu. Ishlinsky;
ρ ₀ - yield strength of the rock,
in addition, on the outer and inner side parts of the matrix, the gaps between the diamonds of the cutting layer are uniformly reinforced with particles of superhard nanomaterial, the linear dimensions of which are 50-150 nm. 2. The crown according to claim 1, characterized in that the lateral outer and inner cylindrical channels of the crown, at least in the first stage of the impregnated matrix layer, communicate with each other by additional channels whose width is (0.6 ÷ 0.8) of the diameter of the cylindrical channel, and the depth is equal to the height of the crest of the matrix.

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