RU2361998C1 - Bore bit with three roller cutters - Google Patents

Abstract

FIELD: oil and gas production.

SUBSTANCE: invention refers to rock destroying tool, notably, to bore cone bits for boring inclined and horizontal boreholes. Roller cutters of the bore bit are equipped with central and peripheral bits of hard alloyed teeth. One roller cutter has one-row peripheral bit, while another has two-row peripheral bit with teeth arranged in a staggered order in a peripheral and before peripheral rows, the third roller cutter has two-row peripheral bit with group arrangement of teeth in a staggered order and with teeth of the before peripheral row arranged in pairs between the groups. On inverse cones of the roller cutters there are cut through slots of depth not less, than weighing of roller cutters relative to bore bit legs. Width of slots on the first and the second roller cutters and opposite to groups of teeth of the third roller cutter is equal to inner distance between base of heads of teeth of the peripheral row, while opposite to in pairs arranged teeth of before peripheral row of the third roller cutter there are cut two slots; also one of slots is two times narrower, than the other. The slots on all roller cutters are made so, that their lengthwise axes are parallel to planes passing through axes of rotation of the roller cutters and are set off relative to these planes in the direction opposite to the direction of rotation of the roller cutters at value y_n: y_n=(y_k-k)/2, where y_k- is distance in plane view from cross axis of the bore bit parallel to axis of the roller cutter to the point of tangency of circumference of the base of the inverse cone of the roller cutter with circumference radius equal to radius of the bore bit; k is set off of roller cutter axis in plane view relative to cross axis of the bore bit.

EFFECT: increased operational life of three roller cutters bore bit under conditions of boring with control over curvature and decreased stick hazard in inclined and horizontal boreholes.

7 dwg

Description

The invention relates to a rock cutting tool, and in particular to cone drill bits for drilling deviated and horizontal wells.

Known drill bit containing cutters mounted on the pins of paws, and carbide teeth mounted on the inner and peripheral crowns of cutters. One of the cones is equipped with a single-row peripheral crown, and the other two with double-row peripheral crowns, in the rows of which the teeth are staggered. Reverse cones of cones and backs of paws are equipped with carbide teeth (Catalog of drill bits of OJSC "Volgaburmash-Samara": "Volgaburmash" - 2003. - P.28).

The disadvantages of the bit are the low milling ability of the peripheral weapons in relation to the well wall and the high probability of the formation of a rod under the peripheral crowns and especially under the pre-peripheral rows of double-row crowns, since these crowns have the largest radius and tooth pitch in the rows and are leading in relation to the central crowns. The smooth surface of the return cones results in a large contact surface with the wall of the well and makes it difficult for the flushing fluid to pass between the return cone and the wall of the well.

These shortcomings lead to inefficient destruction of the peripheral part of the bottom of the well, make it difficult to control curvature when drilling deviated and horizontal wells, increase the energy consumption of rock destruction at the periphery of the well, and lead to the formation of temperature cracks and to thermal wear of a carbide weapon calibrating the well (Roller bits: International translator reference book / Series "Oil and Gas Engineering and Technology" // Edited by V.Ya. Kershenbaum and A.V. Torgashov. - M .: ANO "Technoneftegaz", 2000. - S.199-200).

The closest technical solution to the claimed invention is a three-cone drill bit, including cones mounted on trunnion paws, hard-alloy teeth mounted on central and peripheral crowns, one of which is equipped with a single-row peripheral crown, a second-row peripheral crown with a checkerboard arrangement of peripheral and preperipheral teeth rows and the third - a double-row peripheral crown with the placement of staggered teeth in groups, each of which begins and zak it is cloved in the pre-peripheral row, as a result of which adjacent teeth of the groups form pairs with a minimum pitch (A.S. No. 1627643 USSR, MKI E21B 10/16. Three-cone drill bit / A.N. Popov, B.N. Trushkin, A.V. .Torgashov et al. // Inventions. - 1991. - Bull. No. 6) (Prototype).

The disadvantage of the prototype is that the cones, like the analogue, are made with smooth inverse cones. When drilling inclined and horizontal wells with curvature control, this causes increased loads on the return cones of the cones and their lock bearings and creates conditions for the thermal wear of the cone armament of the cone and the formation of temperature cracks, as well as for gland formation on bits. The latter increases their tack hazard compared to bits equipped with diamond carbide cutting elements.

This conclusion was made when analyzing the causes of gland formation on roller cone bits. For this, cavernograms of wells with large curvature angles were studied. A fragment of the cavernogram of a well drilled in Western Siberia is shown in Fig. 1, in which row 1 corresponds to the nominal radius of the well drilled by a bit with a diameter of 215.9 mm, rows 2 and 3 are the actual radii of the well, measured in two mutually perpendicular directions. In this interval, the zenith angle varied from 61 to 74 °. Figure 1 shows that a significant part of the interval has a well radius of 1 ... 3 mm less than the nominal. This decrease is a consequence of both the formation of a filter cake and the deformation of the wellbore. The position of the cone bit type C in the deformable barrel is shown in figure 2. When deforming the wall 1 of the well, the clearance of the well above the bit decreases, and accordingly, part of the cone 2 is blocked by the wall. Figure 2 shows the displacement of the wall as a result of deformation by 1, 2 and 3 mm. With a shift of 1 mm, the overlap of each cone will be about 43 °, with a shift of 2 mm - about 51 ° and with a overlap of 3 mm - about 57 °, which will be 35, 42 and 48% of the well circumference, respectively. When the bit is raised, these parts of the borehole wall are cut by cones with the formation of an omentum on the bit. And with significant resistance to the cut of the rock, the bit can be stuck in the well.

The invention solves the technical problem of increasing the durability of a three-cone bit in drilling conditions with curvature control and reducing its tack hazard in deviated and horizontal wells.

This problem is solved by the fact that in a three-cone drill bit, including cones mounted on trunnion paws, hard-alloy teeth mounted on central and peripheral crowns, one of which is equipped with a single-row peripheral crown, a second-row peripheral crown with a checkerboard arrangement of teeth of the peripheral and preperipheral rows and the third - a double-row peripheral crown with the placement of staggered teeth in groups, each of which begins and ends with the tooth of the preperipheral row and, as a result of which adjacent teeth of this row form pairs with a minimum step, according to the invention, through grooves of the cones in the light of the teeth of the peripheral rows are made through grooves with a depth not less than the size of the cone of the cones relative to the paws with a cross-section and a width that is constant in trapezoidal length extending to the surface of the inverse cone grooves on the first and second cones and against groups of cloves of the third cone, equal to the distance in the light between the bases of the heads of the cloves of the peripheral row, and against pairwise arranged cloves There are two grooves in the pre-periphery row, one of the grooves being twice as large as the other, and the grooves on all cones are made so that their longitudinal axes are parallel to the planes passing through the rotation axes of the cones and offset relative to these planes in the opposite direction to the cones by the amount

where y _k is the distance in plan from the transverse axis of the bit parallel to the axis of the cone, to the point of contact of the circumference of the base of the inverse cone of the cone with a circle of radius equal to the radius of the bit; K is the displacement of the axis of the cone in terms of the transverse axis of the bit.

Comparative analysis with the prototype shows that the inventive bit differs from it in that through the cones of the cones in the light of the teeth of the peripheral rows are made through grooves with a depth not less than the size of the curtain of cones relative to the paws with a cross-section that is constant along the length of the trapezoidal section and the width of the grooves the first and second cones and against groups of teeth of the third cone equal to the distance in the light between the bases of the heads of the teeth of the peripheral row, and against pairwise arranged teeth two grooves are made in the periphery row, one of the grooves being twice as large as the other, and the grooves on all cones are made so that their longitudinal axes are parallel to the planes passing through the rotation axes of the cones and offset relative to these planes in the opposite direction to the cones , the value of y _p :

Y _n = (y _k -k) / 2,

where y _k is the distance in plan from the transverse axis of the bit parallel to the axis of the cone, to the point of contact of the base of the inverse cone of the cone with a circle of radius equal to the radius of the bit; k is the displacement of the axis of the cone in terms of the transverse axis of the bit.

The proposed drilling three-cone bit in the context shown in figure 3. It contains paws 1, on the trunnions of which the cones are mounted 2. The armament of the first cone includes a single-row peripheral crown of carbide teeth 3, and the other two cones - double-row peripheral crowns, consisting of teeth of the peripheral row 4 and preperipheral row 5. Carbide inserts are installed on the inverse cones of the cones 6 and 7 are made through the grooves, the depth h of not less than value x _of curtain cones.

The position of the peripheral part of the cone 2 relative to the wall of the well 8 is shown in figure 4. The carbide insert 6 and groove 7 are shown on the inverse cone of the cone. The remaining grooves are shown by dashed lines 9. The longitudinal axis of the grooves at the moment of their location in the plane passing through the axis of rotation of the cone and forming the wall of the well have an offset in the direction of rotation of the bit by a value of y _p , calculated by the formula (1).

5, 6 and 7 show views of all three cones from the side of the inverse cones. Numbers of cones conditional. The first cone 2 (see Fig. 5) is equipped with a single-row crown of teeth 3 with a minimum pitch for a specific size of the bit. Grooves are made on the inverse cone 7. The width of these grooves corresponds to the distance between the bases of the tooth heads 3. The second cone 2 (see Fig. 6) is equipped with a double-row crown of staggered teeth 4 of the peripheral row and teeth 5 of the pre-peripheral row. The large distance between the bases of the heads of the teeth 4 of the first row caused the corresponding width of the grooves 7 on this cone. The third cone 2 (see Fig. 7), like the second, is equipped with a double-row peripheral crown, but the teeth in it are arranged in groups. Within the group, the teeth are staggered. Each group begins and ends with a tooth of the pre-peripheral row, for example, with teeth 5 and 10, i.e. teeth 5 and 10 form a pair of teeth with a minimum pitch in the preperipheral row. Within the group, the width of the grooves 12 corresponds to the distance between the bases of the teeth of the peripheral row, as in the second roller cutter. Two grooves are made against paired cloves: one groove 12 is the width corresponding to the diameter of the clove 5, and the second groove 13 is the radius of the adjacent clove 10, which ensures the installation of carbide insert 6 on this part of the inverse cone. The longitudinal axis of all the grooves are tangent to a circle of radius y _n so that their displacement is directed in the direction opposite to the direction of rotation of the cone. The protrusions between the grooves on the reverse cones of all cones are equipped with carbide inserts 6.

The bit works as follows. In the process of drilling cones 2 roll along the bottom, destroying the rock (see figure 3 and 4). The teeth 3 and 4 of the peripheral rows and inserts 6 of the cone cones form (calibrate) the wall of the well 8. The flushing fluid passes between the teeth and along the grooves 7, cooling the calibrating weapon and preventing its thermal wear. When controlling curvature due to the presence of grooves on the surface of the inverse cone, a smaller lateral load on the cones is required compared to serial bits and, accordingly, the load on the castle cone bearings decreases. All this increases the durability of the bit. When the borehole wall is displaced above the bit, the presence of grooves reduces the overlap of the cutters by the wall and resistance to the bit rise. The protrusions on the inverse cones of the cones, equipped with carbide inserts 6, during rotation of the raised bit are able to expand the well above the bit, preventing it from jamming. The group placement of peripheral weapons and grooves on one of the cones, as well as the implementation of grooves of different widths, prevents rake formation on the bottom and protrusions on the walls of the well.

The implementation of weapons cones in accordance with the proposed technical solution will significantly increase the durability of the bits and reduce their tack hazard in inclined and horizontal drilling, which will ensure widespread use of the invention when drilling wells.

Claims (1)

Three-cone drill bit, including cones mounted on trunnion paws, carbide teeth mounted on central and peripheral crowns, one of which is equipped with a single-row peripheral crown, the second - a double-row peripheral crown with a checkerboard arrangement of teeth of the peripheral and pre-peripheral rows and the third - double-row by placing staggered teeth in groups, each of which begins and ends with a tooth of the pre-peripheral row, as a result of which adjacent teeth UPP form pairs with a minimum step, characterized in that through the cones of the cones in the light of the teeth of the peripheral rows are made through grooves with a depth not less than the size of the curtain of cones relative to the paws with a constant trapezoidal section that extends to the surface of the cone and the width of the grooves on the first and second cones and against the groups of teeth of the third cone equal to the distance in the light between the bases of the heads of the teeth of the peripheral row, and against the pairwise arranged teeth of the pre-peripheral row, two grooves are made a, one of the grooves being two times narrower than the other, while the grooves on all the cones are made so that their longitudinal axes are parallel to the planes passing through the rotation axes of the cones, and are displaced relative to these planes in the direction opposite to the direction of rotation of the cones, by an amount y _n :
Y _n = (y _k -k) / 2,
where y _k is the distance in plan from the transverse axis of the bit parallel to the axis of the cone, to the point of contact of the circumference of the base of the inverse cone of the cone with a circle of radius equal to the radius of the bit;
k is the displacement of the axis of the cone in terms of the transverse axis of the bit.

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