RU2183721C2 - Reamer - Google Patents

Abstract

FIELD: mining, particularly, drilling bits for rotary-percussion motion with guide cutting tool for well reaming. SUBSTANCE: reamer leading part has tooth with cutting insert having sharped edges protruding beyond tooth contours and made with steps and cutting edges. Cutting bit has stages with axisymmetrically located and with similar orientation projections and hollows between them and cutting inserts secured in projections and having sharped edges protruding beyond contours of projections. Auger part has a rod with helix whose beginning is spaced from end of the last stage for at least 1/4 diameter of the last stage of cutting bit, but not more of auger helix lead. EFFECT: reduced energy consumption due to reduced energy consumption for removal of rock cuttings. 11 cl, 6 dwg

Description

 The invention relates to drilling equipment, namely to drill bits with a guide cutting tool for expanding a well during rotational motion, and can be used when drilling hard rock in vertical, horizontal or inclined directions, and also as a tool during construction and installation works .

 The prior art drill reamers designed to work with solid rocks. So, in the description of the invention to US patent 4773491, IPC E 21 B 10/26, NPK 175/385, publication date 09/27/88, a drill head is described, which is essentially a drill reamer containing an advance part, destroying the bit and the screw part, the leading part is equipped with a pin with at least one cutting tool fixed in it with cutting edges protruding beyond the contours of the pin, the destructive bit contains at least one step, each of which is made with axially symmetrically arranged protrusions and samples between the protrusions, the protrusions of the last The steps are oriented along the protrusions of the previous step, cutting means are fixed in each protrusion with cutting edges protruding beyond the contours of the protrusion, the screw part contains a rod with screw winding, the beginning of which is spaced at some distance from the end face of the last stage. Moreover, the distance from the end face of the last step to the start of screw winding is not specified, and in the case of a preferred embodiment, as follows from figure 2 of the patent, is not more than 0.15 of the diameter of the last step, which when working, especially in stony rocks and solid material, can lead to compaction of crumbs of destroyed material and consequently increase energy consumption for its transportation by the screw part and increase the required power for operation of the reamer.

 The technical problem to be solved is the reduction of energy consumption for the operation of the reamer. The technical result achieved is to reduce the energy consumption for transporting crumbs of destroyed material when drilling in stone, concrete, brick, etc.

 The invention consists in the following.

 As in the closest analogue presented in US patent 4773491, the reamer contains a leading part, destroying the bit and auger part, the leading part is equipped with a pin with at least one cutting tool fixed therein with cutting edges protruding beyond the contours of the pin , the destructive bit contains at least one step, each of which is made with axisymmetrically located protrusions and samples between the protrusions, and the protrusions of the next step are oriented along the protrusions of the previous stage, in each the protrusion secures a cutting tool with cutting edges protruding beyond the contours of the protrusion, the screw part contains a rod with a screw winding, the beginning of which is separated from the end of the last step, but unlike the closest analogue, the distance from the last step of the destructive bit to the beginning of the screw winding is not less than 1/4 of the diameter of the last step of the destructive bit, but not more than the step of a screw winding.

 The reamer is characterized in that each stage of the destructive bit contains at least three protrusions.

 The drill reamer is characterized in that the cutting means is made in the form of a cutting plate with sharpened front and side edges.

The drill reamer is characterized in that the plates on the leading part pin are fixed along the diameter of the pin, the plates on each protrusion of the steps of the destructive bit are fixed along the corresponding protrusion and are located at an angle other than 0 ^o to the plates mounted on the leading part pin.

 The drill reamer is characterized in that the samples are made through, passing through all the stages of the destructive bit, and have a cylindrical surface.

 The drill reamer is characterized in that the cylindrical surface is made with a constant radius in the cross section of the drill reamer.

 A drill reamer, characterized in that the front part of the leading part pin is equipped with two axisymmetrically arranged ledges, a cutting edge is formed on each ledge formed when the ledge surface intersects with the side surface of the pin, the side is parallel to the cutting inserts of the pin, the back side is perpendicular to the cutting inserts of the pin.

 At the same time, the surface of each step on the pin of the reamer drill from the cutting edge of the step to the end of the pin is proposed to be cylindrical.

 The drill reamer is also characterized in that the front part of the pin of the leading part and each step of the protrusions of the destructive bit is conical, with the same angle at the apex of the cone.

 The drill reamer is characterized in that the radius of the circle described by the lateral edges of the plates of the last stage is larger than the radius of the screw winding, and the diameter of the rod of the screw part is not less than the diameter of the pin of the leading part.

 In addition, the drill expander is characterized in that the plates fixed in the pin and in each protrusion are made with the same dimensions.

 The invention is illustrated by drawings.

 Figure 1 presents a side view of a drill reamer with two stages of a destructive bit.

 Figure 2 is a section aa in figure 1.

 Figure 3 shows a section bB in figure 1.

 Figure 4 shows a section bb in figure 1.

 Figure 5 presents a view of G in figure 1.

 Figure 6 shows a section DD in figure 5.

 The drill reamer is arranged as follows.

The drill reamer contains an advance part 1, destroying the bit 2 and a screw part 3. The advance part 1 is equipped with a pin 4 with at least one cutting means fixed in it, made, for example, in the form of a pair of cutting plates 5 with sharpened front and side edges protruding beyond the contours of the pin 4. Destructive bit 2 may contain one step (not shown), two (figure 1) and more steps, each of which is made with axisymmetric (relative to the axis of rotation of the drill reamer) located protrusions 6 and samples 7 between them moreover, the corresponding protrusions 6 of the previous, for example the first stage 8, and the subsequent, for example the second stage 9, are oriented along one straight line (Figs. 1, 5), in each protrusion 6 there is fixed cutting means made, for example, in the form of a cutting plate 10 with sharpened edges, protruding beyond the contours of the protrusion 6. The screw part 3 contains a rod 11 with a screw winding 12, the beginning of which is spaced from the end face of the last, for example, second stage 9 of the demolition bit 2 by a distance L equal to at least 0.25 of the diameter D _{dol of the} last stage of the demolition bit a 2, but not more than step S _h screw screw 11: D _dol / 4 ≤ L ≤ S _h . The rod 10 of the screw part 3 is connected with the end face of the last stage 9. The rod 10 of the screw part 3 ends with a shank 13 for connection with an electric drive (not shown).

 The front part of the pin 4 of the leading part 1 can be equipped with two axisymmetrically arranged ledges 14 with the side 15 and rear 16 sides, on each ledge 14 a cutting edge 17 is formed (Figs. 1, 4) located on the side surface of the pin 4. The surface of each ledge 14 on the pin 4 of the reamer from the cutting edge 17 to the rear side 16 located at the end of the pin 4 can be made cylindrical with a circle and another line in the base, or with a more complex surface.

 The leading part 1, destroying the bit 2 with steps 9 and 8, the screw part 3 can be performed both in the form of interconnected nodes and parts (not shown), and in the form of a single part, for example, when using a drill reamer as a tool for assembly and construction work.

In a preferred embodiment of the drill reamer, each stage 9 and 8 of the destructive bit 2 contains three protrusions 6, the cutting plates 5 on the pin 4 of the leading part 1 are fixed by the diameter of the pin 4, the cutting plates 10 on each protrusion 6 of the stages 8 and 9 of the destructive bit 2 are fixed along the respective projection 6 along the line centered on the rotational axis of reamer and disposed at an angle different from 0 ^o, the cutting plates 5 secured to the pin 4 anticipatory portion 1. samples 7 are through-passing through all the stages 8, 9 destroyed pilot bit 2, and have a cylindrical surface which may be performed with a constant radius in cross-section reamer (Figure 2) or with a different contour in cross section. The pin 4 of the leading part 1 is equipped with ledges 14 with a cylindrical surface from the cutting edge 17 to the rear side 16 of the ledge 14 (Fig. 5), the lateral side 15 of the ledge 14 is parallel to the cutting inserts 5, and the rear side 16 is perpendicular to the cutting inserts 5 (Fig. 1, 4). The front part of the pin 4 of the leading part 1 and each stage 8, 9 of the protrusions 6 of the destructive bit 2 is conical with the same angle α at the apex of the cone, the radius of the circle D _dol / 2 described by the lateral edges of the plates of the last stage 8 (Fig. 1) is larger than the radius D _dyne / 2 auger winding 12 and the diameter d of the rod 11 _shek screw portion 3 is not smaller than the diameter d 4 _pcs pin anticipatory part 1: D _USD / 2> D _shek / 2, d _shek ≥d _pieces. In addition, the cutting inserts 5 and 10, mounted in the pin 4 and in each protrusion 6, are made with the same dimensions, for example, in the form of a rectangular trapezoid with two adjacent sharpened edges with an obtuse angle between them and an acute angle at the base of the trapezoid equal to half the angle α at the apex of the conical surface of the front parts of the pin 4 and steps 8 and 9 (Fig.6).

 Drill-extender works as follows.

 When the rotary impact drill rotates, the pin 4 of the leading part 1 with cutting means fixed in it, made, for example, in the form of cutting plates 5, destroys the solid material (stone, concrete, brick, etc.) in which drilling is performed due to the high contact stress arising on the sharpened edges of the plates 5 when interacting with the material. The presence of ledges 14 with cutting edges 17 on the pin 4 provides grinding and transportation of the crumbs of the processed material formed after the destruction of the material by cutting means, for example, cutting inserts 5, which improves the productivity of the drill reamer.

 The first stage 8 of the destructive bit 2 expands the well, destroying the material with cutting means, for example, cutting plates 10 fixed in the protrusions 6, causing cracks in the material during impacts and chipping of the material during rotation. When performing the drill of the expander multistage, the second stage 9 (Fig. 1) and subsequent stages (not shown) are wedged by cutting means, for example, cutting plates 10, mounted in protrusions 6 and located along protrusions 6 (and cutting plates 10) of the previous one, for example, the first stage 8, into the cracks formed by the plates 10 of the first stage 8, or by simultaneously cutting the inserts 10 of the adjacent protrusions of 6 stages 8 and 9, contributes to the formation of cracks in the processed material, which increases the destruction of the material while reducing energy opotrebnosti to drive reamer. Due to the mismatch in the orientation of the cutting inserts 5 fixed in the pin 4 and the cutting plates 10 fixed in the protrusions 6 of the steps 8, 9, the drill-extender does not jam when drilling in material with cracks and seams, for example, in masonry. The presence of three or more protrusions 6 ensures that, when the material is chipped, only part of the cutting inserts 10 of the protrusions 6 simultaneously contact with the material, which increases contact stresses in the cutting inserts 10 and the material being processed and contributes to the destruction of the material.

The formed crumb passes through the through samples 7 between the protrusions 6 and is removed by the screw part 3. In this case, due to the separation of the beginning of the screw winding 12 from the end face of the last, for example, second stage 8, to a distance D _dol / 4 ≤ L ≤ S _n, crumb compression is prevented and is not required energy costs for its destruction, which reduces energy costs for the operation of the screw part 3 and the drill-extender as a whole.

 The implementation of the cutting inserts 5 and 10 are the same (Fig.1, 6) increases the manufacturability and maintainability of the drill-expander.

 Sample 7 through, passing through all stages 8, 9 of the destructive bit 2, and giving their surface a cylindrical shape, for example, with a constant radius in the cross section of the drill reamer (figure 2), the surface of each ledge 14 of the pin 4 from the cutting edge 17 to the rear side 16 of the cylindrical side of the 15 ledges 14 parallel to the cutting plates 5, as well as the implementation of the front of the pin 4 of the leading part 1 and each step 8, 9 of the protrusions 6 of the destructive bit 2 with the same angle α at the top of the cone increases ologichnost manufacturing reamer.

The implementation of the drill reamer with a circle radius D _dol / 2, described by the sharpened side edges of the cutting inserts 10 of the last, for example, the second stage 9 (Fig. 1), a larger radius D _SN / 2 screw winding 12 reduces the energy consumption for driving the reamer in connection with a decrease in the friction forces of the side surface of the screw winding 12 with the walls of the well (hole). At the same time, during operation, the screw winding 12 performs the function of a guide surface during vibration and vibrations of the drill-expander, due to the unevenness of the processed material.

The implementation of the diameter d _{SN of the} rod 11 of the screw part 3 of at least the diameter d _{pcs of the} pin 4 of the leading part 1 contributes to the creation of equal strength drill-reamer.

 The presented drill expander is industrially applicable, since the information given in the description of the invention is sufficient for the manufacture of the drill expander at any specialized enterprise with the achievement of the claimed technical result, and additional inventive creativity is not required when developing technical documentation for the drill expander.

Claims (11)

 1. The drill reamer containing the leading part, destroying the bit and the screw part, the leading part is equipped with a pin with at least one cutting tool fixed to it with cutting edges protruding beyond the contours of the pin, the breaking bit contains at least one step, each of which is made with axisymmetrically arranged protrusions and samples between the protrusions, the protrusions of the next stage being oriented along the protrusions of the previous stage, cutting means with cutting edges are fixed in each protrusion, falling beyond the contours of the protrusion, the screw part contains a rod with a screw winding, the beginning of which is separated from the end of the last stage, characterized in that the beginning of the screw winding is separated from the end of the last stage of the destructive bit by a distance of not less than 0.25 of the diameter of the last stage of the destructive bit and not more than auger winding pitch.  2. The reamer according to claim 1, characterized in that each stage of the destructive bit contains at least three protrusions.  3. The drill-extender according to claim 1 or 2, characterized in that the cutting means is made in the form of a cutting insert with sharpened front and side edges. 4. The drill-extender according to claim 3, characterized in that the cutting inserts on the leading part pin are fixed along the diameter of the pin, the cutting inserts on each protrusion of the steps of the destructive bit are fixed along the corresponding protrusion and are located at an angle different from 0 ^o to the cutting inserts, fixed on the pin of the leading part.  5. The drill expander according to any one of paragraphs. 1-4, characterized in that the samples are made through, passing through all stages of the destructive bit and having a cylindrical surface.  6. The drill-extender according to claim 5, characterized in that the cylindrical surface is made with a constant radius in the cross section of the drill-extender.  7. The drill expander according to any one of paragraphs. 1-6, characterized in that the front part of the lead of the leading part is equipped with two axisymmetrically located ledges, on each ledge there is an edge formed when the surface of the ledge intersects the side surface of the pin, the side of the ledge is parallel to the cutting inserts of the pin, and the rear side is perpendicular to the cutting inserts of the pin .  8. The drill-extender according to claim 7, characterized in that the surface of each step on the pin from the edge of the step to the end of the pin is cylindrical.  9. The drill expander according to any one of paragraphs. 1-6, characterized in that the front part of the pin of the leading part and each stage of the protrusions of the destructive bit is made conical, with the same angle at the apex of the cone.  10. The drill-extender according to claim 1, characterized in that the radius of the circle described by the pointed lateral edges of the plates of the last stage is greater than the radius of the screw winding, and the diameter of the rod of the screw part is not less than the diameter of the pin of the leading part.  11. The drill expander according to any one of paragraphs. 1-10, characterized in that the plates fixed in the pin and in each protrusion are made with the same dimensions.

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