WO1993006332A1 - Rock-drilling bit - Google Patents

Abstract

The rock-drilling bit disclosed has cutter assemblies (4) detachably mounted at equal distances apart round the end of the bit (1), a hardmetal alignment spike (6) located in the centre of the end of the bit (1), a shaft (3) round the curved surface of which is spline toothing (16) by means of which the bit (1) can be fitted to a percussion drill (15) operating in the hole, so that it can move longitudinally, and a longitudinal scavenging-air duct (11) through which scavenging air is passed from the rear end (12) of the shaft to the head of the bit (1). In order to ensure a continuous flow of scavenging air, the air duct (11) is connected, by means of at least one radial air-inlet bore (13), to an air space (14) surrounding the rear end (12) of the bit shaft.

Description

"Rock drill bit"

The invention relates to a rock drill bit with cutting inserts, which are attached to the end face of the rock drill bit in the circumferential direction at an equal distance, a carbide tip which is formed in the center on the end face of the rock drill bit, a shank on the circumferential surface of which a multi-spline toothing is formed is, by means of which the rock drill bit is displaceably connectable in the axial direction to a hole hammer, and an axial purging air supply channel, through which purging air can be conveyed from the free shaft end to the end face of the rock drill bit. It has been found that in a combined rotary impact drilling method in which a reversing rotary movement of the rock drill bit is carried out, problems have arisen in connection with conventional rock drill bits, which can be attributed to the fact that the cuttings are removed due to the high effectiveness of the described reversing rotary impact drilling method occurs to an unprecedented extent, could not be reliably accomplished.

The invention has for its object to provide a rock drill bit that can ensure reliable removal of the cuttings generated even when reversing rotary impact drilling is used.

This object is achieved according to the invention in that the axial purging air supply duct is connected via a radial purging air inlet bore to a purging air space surrounding the free shaft end. The radial arrangement of the purge air inlet bore with respect to the shaft ensures that the purge air supply channel is constantly connected to the purge air space surrounding the free shaft end. The previously known scavenging air supply channels, the openings of which are designed as an axial extension of the scavenging air supply channel on the free end face of the shaft of the rock drill bit, are used for when the percussion piston hits the percussion hammer locked for a period of time. This results in irregularities with regard to the purging air supply to the bottom of the borehole. These irregularities no longer occur in the case of the purge air inlet bore which runs radially according to the invention.

A further improvement in the purging air supply and distribution on the end face of the rock drill bit or on the bottom of the borehole results if the axial purging air supply channel in front of the end face of the rock drill bit is divided into purging air supply bores, each of which is located on the end face of the rock drill bit in a main material discharge groove opens out, which is formed in the radial direction between in each case two of the cutting lugs equally spaced in the circumferential direction. This ensures a uniform supply of purging air in the area of the face of the rock drill bit that is particularly important for a uniform removal of the material obtained as cuttings.

If the axial purging air supply duct is inclined with respect to the central axis of the rock drill bit and is extended over a section to an opening, the purging air supply bores leading to the other openings being connected to the purging air supply duct inclined to the central axis of the rock drill bit, it is possible for all of them Drilling from one side of the rock drill bit, namely from the free end face of the crown section forth to manufacture. It is no longer necessary to implement the rock drill bit in the production of the purging air supply channel and the purging air supply bore. Furthermore, the number of bores is reduced, since a section of the purge air supply channel on the crown section side can form a purge air supply bore.

In the embodiment of the rock drill bit described above, the shaft end can advantageously be closed on its free end face. Since the free end face of the shaft end which is then available as a stop surface for the percussion piston is considerably increased, there is a lower surface pressure between the striking surface of the percussion piston and the free end face of the shaft end, so that longer service lives for the percussion piston and for the shaft of the Rock core bits can be achieved than would be possible with a shaft end that is open in the axial direction and thus has an annular end face.

If the axial purging air supply of the rock drill bit from a purging air space surrounding the free shaft end to the face of the rock drill bit is achieved by a free annular space surrounding the outer diameter of the shaft, which is interrupted in circumferential direction by milling, by means of which a guide section which radially guides the rock bit is interrupted , is connected to the purge air space and through purge air supply holes Connected to the face of the rock drill bit, which purging air supply holes run through the crown section of the rock drill bit, the rock drill bit can be made with a symmetrical cross section over its entire length, which results in particularly favorable strength properties of the rock drill bit. This is of considerable importance since the mechanical stress on the rock drill bit is of considerable magnitude due to the action of the down-hole percussion hammer.

The rock drill bit described above can advantageously have two purging air supply holes.

A mouth of the scavenging air supply bores on the end face of the rock core bit can be reached in a particularly simple manner if the scavenging air supply bores are inclined radially inward towards the face side of the rock core bit.

If the mouths of the purging air supply holes are immediately adjacent to the hard metal centering tip, it is reliably prevented that cuttings accumulate in the central area of the drill hole or the bottom of the drill hole, which leads to a disturbance of the drilling process, e.g. could lead to an unbalanced load on the rock drill bit.

A further improvement in the removal of the falling material from the bottom of the borehole results if auxiliary material removal centers are formed in the radial outer sections of the cutting inserts.

If the hard metal centering tip protrudes with its free end in the axial direction of the rock drill bit by a distance above the cutting inserts, the rock drill bit is correctly centered on the center of the bottom of the borehole, which results in a comparatively uniform annular space surrounding the circumference of the rock drill bit, which results in the uniform removal of the cuttings accumulating on the borehole and transported radially outwards by the main and auxiliary material discharge grooves is made considerably easier.

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A uniform removal of the borehole bottom, which is advantageous for centering the rock drill bit, is achieved if the cutting inserts are arranged on their respective cutting diameter in such a way that their cutting grooves, which are produced when drilling is preferably reversed between 180 degrees and 240 degrees, overlap.

If the free end face of the shaft end is at least as large as the striking surface of the striking piston, there is a further reduction in the surface pressure with the corresponding advantages in terms of tool life.

In the following, the invention is explained on the basis of an embodiment form explained with reference to the drawing. Show it:

1 shows an embodiment of the rock bit according to the invention, partly in section;

FIG. 2 shows a top view of the end face of the rock drill bit shown in FIG. 1;

3 shows the rock drill bit shown in FIG. 1 following an in-hole percussion hammer;

4 shows a second embodiment of the rock drill bit according to the invention, partly in section;

FIG. 5 shows a top view of the end face of the rock drill bit shown in FIG. 4;

FIG. 6 shows the rock drill bit shown in FIG. 4 following an in-hole percussion hammer;

7 shows a third embodiment of the rock drill bit according to the invention, partly in section;

FIG. 8 shows a top view of the end face of the rock drill bit shown in FIG. 7; and

Fig. 9 the rock drill bit shown in Fig. 7 in Connection to a punch hammer.

A rock drill bit 1 shown in FIG. 1 has a crown section 2 oriented towards the bottom of the borehole and a shaft 3 oriented towards the end of the rock drill bit 1 remote from the bottom of the borehole.

In the illustrated embodiment of the rock drill bit, four cutting inserts 4, each of which is equipped with cutting elements 5, are detachably attached to the end face of the rock drill bit 1 or of the crown section 2 shown on the bottom of the borehole.

The cutting inserts 4 are arranged in a symmetrical manner on the end face of the rock drill bit 1, namely in the circumferential direction of the rock drill bit on a radial outer section of the end face of the rock drill bit are equally spaced. A hard metal centering tip 6 is formed in the central section of the end face of the rock drill bit 1 free of the cutting inserts 4. As can be seen from FIG. 1, this protrudes with its free tip by an excess or distance x beyond the cutting elements 5 of the cutting inserts 4 closest to the bottom of the borehole. This ensures reliable centering of the rock core on the bottom of the borehole.

Between the mutually spaced cutting inserts 4, four main material removal grooves 7 formed, which are formed by the approximately axially oriented wall surfaces of the cutting inserts 4 and by the cutting insert-free sections of the end face of the rock drill bit 1. By means of these main material removal grooves, material obtained as cuttings can be transported away from the central area of the bottom of the borehole to the annular space surrounding the rock core 1.

In the illustrated embodiment, two auxiliary material removal grooves 8 are formed in the radial outer sections of the cutting inserts 4, which contribute to the removal of the material obtained as cuttings from the bottom of the borehole into the annular space.

In the main material removal grooves 7, a mouth 9 is formed which is directly adjacent to the hard metal centering tip and which is in each case the opening area of a flushing air supply bore 10, which is formed in the crown section 2 of the rock core and has an axial center line of the rock core 1.

Each of the four purging air supply bores in the exemplary embodiment shown merges at its end remote from the end face into a purging air supply duct 11, which supplies the purging air supply bores 10 with purging air and which penetrates the shaft 3 of the rock drill bit 1 in the center in the axial direction.

Near the free shaft end 12 of the shaft is in the At least one radial purge air inlet bore 13 is formed in the wall of the shaft 3 surrounding the purge air supply duct 11. Through this radial purging air inlet bore or these radial purging air inlet bores 13, the purging air supply channel 11 leading to the bottom of the borehole is connected to a purging air space 14 surrounding the free shaft end 12 of the shaft 3 of the rock drill bit 1, the purging air between the inner circumferential wall of an in-hole hammer 15 and the free shaft end 12 of the shaft 3 the rock drill bit 1 is formed.

On the outer circumference of the shaft 3 there is furthermore a splined toothing 16 which engages with a splined toothing part 17 designed accordingly on the inner peripheral wall of the punch hammer. The engagement of the multi-spline toothing 16 on the side of the rock drill bit in the multi-spline toothing part 17 on the side of the percussion hammer ensures a rotationally fixed connection between the down-hole percussion hammer 15 and the rock drill bit 1 without an axial movement of the stone drill bit 1 with respect to the down-hole percussion hammer 15 being prevented.

Due to the radial arrangement of the at least one purging air inlet bore 13 provided on the free shaft end 12, an undisturbed purging air supply from the purging air space 14 into the purging air supply duct 11 is also ensured when a percussion piston 18 of the down-hole hammer 15 for transmitting a percussion impulse to the rock drill bit 1 strikes against the free end face of the shaft 3, as shown in the right half of FIG. 3.

An embodiment of the rock bit shown in the Figures 4 to 6 differs from that shown in Figures 1 through 3, characterized in that the Spülluftzufuhrkanal 11 extends inclined with respect to the center axis of the rock bit 1, ie, the means ^¬ axis of Spülluftzufuhrkanals and 4 the vertical central axis of the rock drill bit 1 enclose a comparatively small angle. Furthermore, the axial purging air supply duct 11 shown in FIG. 4 is extended beyond its connection point to the purging air supply bores 10, so that it is connected to the crown section

2 of the rock core 1 through section 11a replaced a purge air supply bore 10 and is extended to a mouth 9. The other purging air supply bores 10, which lead to the other mouths 9, are in the transition area between the crown section 2 and the shaft

3 of the rock drill bit 1 is connected to the scavenging air supply duct 11 inclined to the central axis of the rock drill bit 1.

In this embodiment, the purge air supply channel 11 can be drilled as a blind hole from the free end face of the crown section 2 of the rock drill bit 1. Accordingly, the shaft end 12 is closed on its free end face. The supply of the scavenging air supply duct 11 closed on the end face of the shaft end 12 takes place through the radial purging air inlet bores 13. Since the shaft end 12 is closed on its free end face, the entire, closed free end face of the shaft end 12 is available as the stop face for the striking piston 18.

An embodiment of the rock drill bit shown in FIGS. 7-9 differs from the embodiments shown in the above in that the supply to the free end face of the crown section 2 of the rock drill bit 1 instead of through a flushing air arranged more or less centrally in the rock drill bit 1 ¬ guide channel 11 through an annular space 21 surrounding the outer diameter of the shaft 3 of the rock drill bit 1, which is closed to the outside by a corresponding section of the housing of the down-hole hammer 15.

To the scavenging air space 14 surrounding the free shaft end 12, the annular space 21 surrounding the shaft 3 is connected via millings 19 which interrupt a guide section 20, by means of which the rock drill bit 1 is guided in the radial direction, in the circumferential direction.

The annular space 21 is connected to the free end face of the crown section 2 of the rock drill bit 1 via the purging air supply bores 10, two of which are provided in the exemplary embodiment shown and which face the free end face of the crown section 2 of the rock Drill bit 1 are inclined radially inwards in the direction of the main axis of the rock drill bit 1.

This configuration of the rock drill bit 1 enables a symmetrical cross section to be achieved over the entire length of the rock drill bit 1, as a result of which the strength properties of the rock drill bit 1 are advantageously influenced.

Claims

PATENT CLAIMS

1. Rock drill bit with cutting inserts (4), which are attached to the end face of the rock drill bit (1) in the circumferential direction at an equal distance, a carbide centering tip (6), which is formed centrally on the end face of the rock drill bit (1), a shaft ( 3), on the circumferential surface of which a multi-spline toothing (16) is formed, by means of which the rock drill bit (1) can be connected to an down-hole hammer (15) displaceably in the axial direction, and an axial purging air supply channel (11) through which purging air is released Shaft end (12) can be conveyed to the end face of the rock drill bit (1), characterized in that the axial purging air supply duct (11) is connected via at least one radial purging air inlet bore (13) to a purging air space (14) surrounding the free shaft end (12).

2. Rock drill bit according to claim 1, in which the axial purge air supply channel (11) in front of the end face of the rock drill bit (1) is divided into purge air supply holes (10), each of which on the end face of the rock drill bit (1) opens into a main material removal groove (8) which is formed in the radial direction between each of two cutting inserts (4) which are equally spaced in the circumferential direction.

3. Rock drill bit according to claim 1 or 2, wherein the axial purging air supply channel (11) is inclined with respect to the central axis of the rock drill bit (1) and is extended over a section (11a) to a mouth (9), the to other outlets (9) leading purging air supply bores (10) are connected to the purging air supply channel (11) inclined to the central axis of the rock drill bit (1).

4. Rock drill bit according to one of claims 1 to 3, in which the shaft end (12) is closed on its free end face.

5. Rock drill bit with cutting inserts (4), which are attached to the face of the rock drill bit (1) in the circumferential direction at the same distance, a hard metal centering tip (6), which is formed centrally on the face of the rock drill bit (1), a shaft (3), on the circumferential surface of which a multi-spline toothing (16) is formed, by means of which the rock drill bit (1) can be displaceably connected in the axial direction to a down-hole hammer (15), and an axial purging air supply, through which purging air from the free shaft end (12) to the forehead ¬ side of the rock drill bit (1) can be conveyed, characterized ge indicates that the axial purging air supply from a purging air space (14) surrounding the free shaft end (12) to the end face of the rock drill bit (1) through an external diameter of the shaft (3) of the rock drill bit (1) surrounding free annular space (21), which is interrupted in the circumferential direction by milling (19) by means of which a guide section (20) guiding the rock drill bit (1) radially is interrupted in the circumferential direction Purging air space (14) is connected, and is formed by purging air supply bores (10) which connect the annular space (21) through a crown section (2) of the rock drilling crown (1) on the end face thereof.

6. Rock drill bit according to claim 5, in which two flushing air supply bores (10) are provided.

7. rock drill bit according to claim 5 or 6, wherein the purge air supply holes (10) to the end face of the Gesteins¬ drill bit (1) be inclined radially inwards.

8. Rock core bit according to one of claims 2 to 7, in which the mouth (9) of the purge air supply bore (10) is directly adjacent to the hard metal centering tip (6).

9. Rock drill bit according to one of claims 1 to 8, in which auxiliary material removal grooves (8) are formed in the radial outer sections of the cutting inserts (4).

10. Rock core bit according to one of claims 1 to 9, in which the hard metal centering tip (6) with its free end in the axial direction of the rock core bit (1) by one Excess or distance x protrudes over the cutting inserts (4).

11. A rock drill bit according to one of claims 1 to 10, in which the cutting inserts (4) are arranged on their respective cutting diameters such that their cutting grooves, which are produced when drilling is preferably reversing between 180 degrees and 240 degrees, overlap.

12. Rock drill bit according to one of claims 1 to 11, in which the free end face of the shaft end (12) is at least as large as the striking surface of the percussion piston (18).