WO1992013169A1 - Drilling bit for a rock drill with axial pressure and axial percussion - Google Patents

Abstract

In the bit proposed, the hard-metal pins (6) set in the face (3) of the bit are inclined at an angle of about 20 towards the direction of motion with respect to the longitudinal axis. The pins (6) are also inclined slightly, by about 5, towards the centre of the bit. This significantly increases the drilling efficiency of the bit for an unchanged drill drive power.

Description

 Description

For a rotating rock drill bit working with axial pressure and impacts

The invention relates to a drill bit intended for a rotating rock drill operating with axial pressure and impacts, the end face of which has a plurality of pocket holes with hard metal pins protruding therein and projecting over the end face of the drill head.

Drill bits of the above type are used in the production of boreholes for rock destruction. With them, the hard metal pins are inserted in the axial face of the drill bit and have a rounded face. Obviously, with this orientation of the hard metal pins, the primary consideration was that the impact forces reaching axially in the drill bit should be supported by the hard metal pins axiaL.

Drilling holes in rock is a very time consuming and costly job. To reduce drilling times, drilling tools with ever increasing efforts are being used today. Furthermore, efforts are being made to increase the drilling capacity by means of rinsing out, by means of an improved discharge of the pieces of rock detached from the drill bit. However, the known measures for improving the drilling performance only led to relatively limited success.

Spare sheet The invention is based on the problem of designing a drill bit of the type mentioned at the outset in such a way that it increases the drilling performance with the same drive performance.

This problem is solved according to the invention in that the hard metal pins are inclined in the running direction by an oblique course of the blind holes.

As a result of this design, the hard metal pins penetrate the rock more easily as a result of the rotational movement and axial force than with the known drill bits. They are therefore able to loosen rocks with less energy. Surprisingly, the oblique carbide pins can protrude further from the end face than in the known drill bits, without tending to break off. This is due to the fact that the hard metal pins are loaded obliquely by the simultaneous action of the compressive and impact force directed in the axial direction and the cutting force resulting from the rotation of the drill bit. Axially aligned hard metal pins are therefore subjected to bending, while the oblique hard metal pins arranged according to the invention are oriented approximately as the resultants of axial force and circumferential force run, so that they are essentially only axially stressed.

Due to the larger projection of the hard metal pins, there is more space between the end face of the drill bit and the tips of the hard metal pins for rinsing loose rocks, which in turn increases the performance of the drill bit. The inclination of the hard metal pins must be adapted to the type of rock. For commonly occurring rock types, it has proven to be expedient if the inclined position of the hard metal pins in the running direction is approximately 10 to 30 degrees to the axial direction of the drill bit.

The breaking away of rocks by means of the hard metal pins can be further promoted in that, according to a development of the invention, the hard metal pins are inclined in addition to the inclination in the running direction towards the center of the drill bit. Such an inclination avoids that the hard metal pins only produce concentric grooves in the rock, between which there remain webs on which the end face of the drill bit is seated. By slanting towards the center of the drill, these webs are more easily destroyed.

The extent of the inclination of the carbide pins towards the center of the drill bit also depends on the type of rock. It has proven to be advantageous for most cases if the inclination of the hard metal insert to the center of the drill bit is approximately 5 degrees.

It contributes to a further increase in drilling performance if the hard metal pins are arranged on different partial circles.

It is also advantageous if the hard metal pins have a conical tip. So far, such tips have been dispensed with, because with conventional drill bits, these tips would dull too quickly. In the case of very inclined L lten carbide pins, however, there is a self-sharpening effect, so that the service life is surprisingly long. A sluggishness of the drill bit due to increased friction of its lateral surface against the wall of the borehole as a result of rock pieces jamming there can be ruled out in a simple manner by inserting slightly radially projecting hard metal pins with a rounded end surface in its lateral surface.

The stability and service life of the drill bit can be increased many times over if the hard metal pins of the lateral surface protrude slightly less radially outwards than the hard metal pins on the truncated cone surface. This also increases the smooth running of the drill bit.

It is particularly advantageous in terms of stability and smooth running if two rows of hard metal pins are arranged on the lateral surface with a different axial distance from the end face of the drill bit and the hard metal pins of the row furthest from the end face project less radially outwards than that carbide pins arranged on the row closer to it. With a drill bit of this type, apart from the hard metal lamellas on the end face, initially only the hard metal pins work on the cone istu surface. After partial wear, the hard metal pins of the row adjacent to the end face start to work on the lateral surface of the drill bit. If these hard metal pins are also worn, the hard metal pins arranged even further away from the end face are used. According to another embodiment of the invention, the risk of the drill bit jamming in the borehole can be countered by the fact that the division of the hard metal pins in the end face is fixed in such a way that there is a moment-free support in axial direction with respect to the axis of rotation.

The invention permits numerous exemplary embodiments. To further clarify its basic principle, one of these is shown in the drawing and is described below. The drawing shows in

1 shows a side view of a drill bit designed according to the invention,

2 is a plan view of the drill bit,

3 vertical sections through partial areas of the drill bit to illustrate the alignment of its hard metal pins.

The drill bit shown as a whole in FIG. 1 has a shank 1 and a larger-diameter drill bit head 2 with a flat end face 3, a cylindrical outer surface 4 and a Kege Istumpff Lache 5 connecting the end face 3 with the outer surface 4. From the end face 3 protrude hard metal pins 6, all of which are slightly very inclined in the tangential direction and towards the center of the drill bit and each have a sharp, conical tip.

Also in the Kege Istump f Lache 5 hardmetal L Isti fte 7 are arranged, which are also arranged in tangent ia L direction, ie obliquely in the running direction and a Kegel¬ tip on egg. In the cylindrical lateral surface 4, hard metals Lsti fte 8, 8a are arranged in a radial orientation, which have a rounded end surface, which protrudes slightly from the lateral surface 4. The hard metals 7 located on the frustoconical surface 5 project radially slightly further than the adjacent hard metal pins 8 a in the lateral surface 4. The hard metals 8 arranged further down in FIG. 1 are again slightly in relation to the hard metal pins 8 a set back in the radial direction.

FIG. 2 shows that at least the hard metal pins 6, 6a, 6b, 6c arranged near the drill bit center 9 are located on different part circles, so that they do not work one after the other when drilling. FIG. 2 also shows four rinsing channels 10, 10a, 10b, 10c, through which the washing-up liquid which discharges the loosened rocks is fed.

FIG. 3 illustrates how the hard metal pins 6, 7, 7a are aligned. The superimposed, left hand Darste L lungs each show a view of a hard metal pin 6, 7, 7a tangential to the drill bit, while the right-hand representations each show a view rotated by 90 degrees. The upper left illustration shows that the hard metal L Lsti ft 6 is tilted about 5 degrees to the center of the drill bit. The direction to the center of the drill bit was indicated by an arrow 12. The upper right illustration shows that the hard metal lsti ft 6 is simultaneously tilted by 20 degrees in the running direction indicated by a leftover 13. The blind hole 11 receiving it must of course be drilled accordingly at an angle. The hard metals 7, 7a are arranged differently on the Kege Istumpff Lache 5. The hard metal pins 7 located closer to the center of the drill bit, which are shown in the middle part of FIG. 3, do not have an inclined position with respect to the center of the drill bit. The outer hard metal pins 7a are tilted 30 degrees outwards from the center of the drill bit. They protrude slightly beyond the outer contour of the radially aligned hard metal pins 8. All hard metal pins 7 and 7a are tilted by 20 degrees in the running direction.

List of the reference symbols used

1 shaft

2 drill bit heads

3 end face

4 outer surface

5 kegs actual surface

6 hard metal sti ft

7 carbide pin

8 carbide pin

9 center of drill bit 10 rinsing channel

11 blind hole 12 arrow l 13 arrow l

Claims

Claims

1. For a rotating rock drill working with axial pressure and impacts, certain drill bits, the end face of which has several blind holes with soldered therein, projecting over the end face of the drill head, hard metal pins, characterized in that the hard metal pins (6) have an oblique course the blind holes (11) are inclined in the running direction.

2. Drill bit according to claim 1, characterized in that the oblique L lung of the hard metal pins (6) protrudes in the direction of travel approximately 10-30 degrees to the axis of the drill bit.

3. Drill bit according to claims 1 or 2, characterized ge indicates that the hard metal pins (6) are inclined in addition to the inclination in the running direction towards the center of the drill bit.

4. Drill bit according to claim 3, characterized in that the oblique lung of the hard metal pins (6) towards the center of the drill bit is approximately 5 degrees.

5. Drill bit according to at least one of the preceding claims, characterized in that the hard metal pins (6) are arranged on different pitch circles.

6. Drill bit according to at least one of the preceding claims, characterized in that the hard metal pins (6, 7) have a conical tip.

7. Drill bit according to at least one of the preceding claims, characterized in that slightly radially projecting hard metal pins (8) with a rounded end face are used in its jacket surface 4).

8. Drill bit according to claim 7, characterized in that the hard metal pins (8, 8a) of the lateral surface (4) project slightly less radially outwards than the hard metal pins (7) on the kege actual surface (5).

9. Drill bit according to claim 8, characterized in that on the lateral surface (4) with different axial distance to the end face (3) of the drill bit two rows of hard metal rods (8, 8a) are arranged and the hard metal pins (8) of the row furthest from the end face (3) project less radially outwards than the hard metal pins (8a) arranged on the row closer to it.

10. Drill bit according to at least one of the preceding claims, characterized in that the division of the hard metal pins (6) in the end face (3) is so defined that there is a torque-free support in axial direction in relation to the axis of rotation .