RU2222683C2 - Roller bit - Google Patents

Abstract

FIELD: rock breaking tools. SUBSTANCE: roller bit includes arms making body of bit, rolling cutters mounted in bearing assemblies and nozzle with cone internal hydraulic conduit located in central hole of body. Six longitudinal slits are made in wall of nozzle. Three equal slits with larger areas of outlet sections which expand along length from center to periphery of roller bit are arranged uniformly and are strictly directed into spaces between rolling cutters and three equal slot-shaped slits with smaller areas of outlet sections have identical width and are directed with inclination to surfaces of rolling cutters and their axes in plan are displaced with reference to axes of rolling cutters in direction of rotation of bit through angle α = 15÷25^°. Summary areas of outlet sections of larger and smaller slits are interrelated by following relationship ΣF_l.a/ΣF_s.a = (2,0÷3,5), where ΣF_l.a and ΣF_s.a are summary areas of outlet sections of correspondingly larger and smaller slits, sq mm. EFFECT: coverage with jet action of entire surface of face, improved cleaning of rolling cutters from driven rock, counteraction to balling at bit, rational distribution of flows of flushing fluid, increased technical and economic indices of drilling and raised operational reliability of roller bit. 2 dwg

Description

The invention relates to a rock cutting tool, and in particular to cone drill bits.

A drill bit is known, the flushing system of which includes a nozzle installed along the axis of the bit and a nozzle located inside the nozzle at its lower end [1].

The disadvantage of the flushing unit of this bit is the locality of the action of the jet of flushing fluid flowing out of the nozzle, the dependence of the radius and area of its action on the flow of the drilling fluid and the speed of the bit.

A cone drill bit is also known, the flushing system of which consists of a central nozzle installed in the nipple, with a conical section on the inner surface, lateral, directed into the openings between the cone cuts, the number of which corresponds to the number of cones, and radial holes located symmetrically between the cuts and directed into the suprahepatic space [2].

During the operation of such a bit, the streams of the cleaning agent exiting from the radial holes cannot take any real part either in the cleaning of the cutter cone of the bit cone and from the bottom plane, since they are directed perpendicular to the axis of the bit past the cone surface. The kinetic energy of these radial streams of the cleaning agent will be used irrationally. Moreover, these flows can only prevent the removal of cuttings.

Known cone drill bit containing mounted on the supports of the cone and located in the Central hole of the cavity nozzle with a conical internal hydraulic channel, in the wall of which there are longitudinal slots, the number of which is equal to the number of cones [3].

The disadvantage of this washing system is the limited area of the jet effect locally directed to the cone or to the face plane, and the impossibility of their simultaneous cleaning. Cleaning the peripheral zone of the face with such a washing pattern for any orientation of the slots will be insufficient.

The closest in technical essence and the achieved result is a three-cone drill bit, the flushing system of which consists of a nozzle with a conical internal hydraulic channel located in the central hole of the bit, in the wall of which there are six longitudinal cuts of the same length [4].

During operation of the bit with such a flushing scheme, the peripheral, most sludge-loaded face zone is not washed enough. The jets of flushing fluid directed to the surface of the cones along their axes, due to their frontal impact, do not sufficiently wash off the sludge from the armament and do not form the directions of upward flows, which generally reduces the efficiency of the drilling process. These circumstances have a particularly negative effect on the operation of large diameter drill bits with large cone sizes and tooth height.

The purpose of the present invention is to enhance the jet effect on cleaning the face, especially its periphery, to improve the cleaning of surfaces and teeth of cones from cuttings, to prevent gland formation on the bit, the rational organization of transverse and upward flows of washing liquid by choosing the optimal shape and placement of nozzle slots, as well as optimization the ratio of the areas of their output sections.

This goal is achieved by the fact that the central nozzle of the bit is used with a conical internal hydraulic channel, in the wall of which six longitudinal slots are made. Three large exit sections and equal slots are made uniformly expanding in length from the center to the periphery of the bit and directed strictly into the inter-cone spaces. The three smaller sections of the exit sections of the slit-shaped form of constant section are made of the same width, and their axes are shifted in plan relative to the axes of the cones in the direction of rotation of the bit depending on the height of the teeth of the cones by an angle α = 15 ÷ 25 ° (from 15 ° for bits of type " T "up to 25 ° for bits of type" M "). The total area of the outlet cross sections of the larger and smaller slots, depending on the estimated volume of sludge removal per unit time, are interconnected by the following relationships:

ΣF _PSU / ΣF _Mn = (2.0 ÷ 3.5),

where ΣF _BP and ΣF _MP - the total area of the output sections, respectively, of larger and smaller slots, mm ² .

Depending on the types of bits, the ratio of areas is 2.0 for bits of type "T" and 3.5 for bits of type "M".

The implementation of a conical internal hydraulic channel in the central nozzle with the six above-mentioned slots allows the bit to overcome the volume of flushing fluid in the bottomhole zone and direct the streams at the same time to clean the cutters and the face plane with compact elongated jets of the volume in the above proportion, as well as maximize the flow exit from the nozzle to the surface of the face and cones. The implementation of three large output cross-sections of slots uniformly expanding along the length from the center to the peripheral part of the bit allows in the process of its operation to strengthen and make more uniform cleaning along the entire radius of the face, including in the most sludge-loaded peripheral zone, and purposefully point the cuttings in the direction from center to the periphery of the face and further into the annulus. In this case, the implementation of three smaller slits of a slit-like shape of constant cross section and their orientation with an offset in the plan of the axes by an angle of 15 ÷ 25 ° with respect to the axes of the cones will positively affect the washing off of the sludge from the cone armament, since the jets will be directed closer to the tangent along the axes relative to the teeth of the cones and clean them before the moment of new coming into contact with the rock face. Such a direction of fluid flows in relation to the working surfaces of the cones will enhance the effect of cleaning weapons, preventing the complete extinction of the energy of these flows, and will improve the cleanliness of the arms of cones and cleaning the face. Counteraction of the gland formation on the bit and uniform cleaning of the face will occur simultaneously.

The length of all six slots of the nozzle is chosen so as to cover the entire surface of the face and cones gradually increasing from the center with a jet action, eliminating the effect of liquid jets on the well wall. The length of the jets of fluid directed to the cones should be close to the length of the forming cones, and the length of the jets directed into the inter-cone spaces should be close to the radius of the face.

The cone drill bit consists of a body composed of paws 1 and cones 3 mounted on supports 2. At the end of the nipple part, a nozzle 4 is installed in the center of the bit with an internal conical hydraulic channel and six slots made on the generatrix of the cone. Of these, three slots 5, large in area of the output cross sections, are made uniformly expanding in length and directed into the inter-cone spaces 6, and three smaller slit-shaped cuts 7 are made of constant section with a shift of their axes in the plan in the direction of rotation of the bit by 15 ÷ 25 ° relative to the axes of the cones 3.

The central nozzle is installed and fixed in the bit so that the large slots in the output cross-sectional areas are oriented strictly in the inter-cone spaces, and the three smaller ones, respectively, with their axes shifted by l5 ÷ 25 ° from the axes of the cones. Moreover, from the point of view of hydrodynamics, the maximum possible approximation of the central nozzle to the surface of the cone and the bottom will be rational.

The bit works as follows. After it is lowered into the well through the drill pipe string through the central nozzle 4, flushing fluid is supplied to the bottom hole. When scrap streams of fluid flowing from three large-area slots 5, evenly wash the face plane, while ensuring the movement of sludge from the center to the periphery of the face and then through the annulus to the surface. jets of liquid flowing out of three smaller slots 7 and directed obliquely to the surfaces and teeth of the cones, clean the armament of cones immediately before their contact with the rock bottom, counteracting gland formation on cones and in the supra-conic zone. This distribution of bottom-hole flows allows the bit to constantly work with clean weapons of cone, to minimize the time spent by cuttings in the area of the bit, to rationally guide the transverse and vertical flows of flushing fluid. As a result, all kinetic energy of the flow will be spent only on the process of cleaning the face and roller cutters, which is especially important for the operation of bits with large teeth in rocks prone to gland formation.

Figure 1 shows a General view of the bit, figure 2 is a top view of the bit and the orientation of the slots of the Central nozzle in the bit.

The proposed hydraulic washing circuit of the bit makes it possible to implement the invention. It was established experimentally in bench and field conditions that the above ratio of the areas of the outlet cross sections, depending on the strength of the drill bit and the expected volume of cuttings per unit time, is the most optimal and provides a significant increase in the mechanical speed of drilling and penetration to the bit.

Sources of information

1. Copyright certificate No. 1514900, Е 21 В 10/08, 1989, bull. Number 38.

2. Copyright certificate No. 1046466, E 21 B 10/18, 1983, bull. Number 37.

3. Copyright certificate No. 891883, E 21 B 10/08, 1981, bull. Number 47.

4. Patent of Ukraine No. 14853 A, E 21 B 10/18, 1997, bull. No. 3.

Claims (1)

Roller cone bit consisting of paws making up the body of the bit, mounted on the supports of the cones and located in the central hole of the nozzle body with a conical internal hydraulic channel, in the wall of which there are six longitudinal slots, characterized in that there are three large output sections and are equal between the slots are made uniformly expanding in length from the center towards the periphery of the bit and directed strictly into the inter-cone spaces, and three smaller in the area of the output sections and also slits of a slit-like shape are made of the same width and are directed obliquely to the surfaces of the cones, and their axes in plan are offset relative to the axes of the cones in the direction of rotation of the bit by an angle α = 15–25 °, while the total areas of the output sections of the larger and smaller cuts are connected between the following relationships: Σf _bp / ΣF _MP = (2.0 ÷ 3.5), where Σf _bp and ΣF _MP - the total area of the output sections, respectively, of larger and smaller slots, mm ² .

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