EP0054721A1 - Drill bit, especially rock drill bit - Google Patents

Abstract

A drill bit is intended for rotary percussion drilling and is to be used as a rock drill bit. It has a shank with a hole drilling head which carries a cutting rim. So that the percussion energy applied to the drill shank is transmitted to the cutting rim as fully as possible, the drill bit is of hole design in the transition area between the shank and the cylindrical wall of the hole drilling head, and an inner wall of this hole drill-bit section forms a hole-cutting- base tapered in the direction of the drill-bit shank. <IMAGE>

Description

The invention relates to a drill, in particular a rock drill, according to the preamble of claim 1.

Drills of this type are provided as tools for rotary drilling on electric hand tools. The inner bottom of the hollow core bit is usually flat and lies approximately perpendicular to the axis of the drill. With these drills, a significant part of the impact energy is converted into sound energy and is therefore lost to the work of the drill. The invention is based on the knowledge that this phenomenon is essentially caused by the right-angled position of the crown bottom to the drill axis. The axially applied impact forces are only redirected to a small extent into the cylindrical wall of the hollow drill bit, so that the greatest proportion of the energy of the impact pulses on the bottom surface of the drill bit emerges unused as a sound wave.

The invention has for its object to design the generic drill so that the impact energy applied is better utilized and thus the effect degree of the drill equipped with the drill is improved.

This object is achieved with the characterizing part of claim 1.

As a result of the tapered course of the crown base, an extended transition area from the drill shaft to the cylindrical wall of the hollow drill bit and thus a largely complete deflection of the impact impulses from the drill shaft into the drill bit is achieved. As a result, a high impact force corresponding to the impact energy applied is available in the cutting ring area, so that the desired high efficiency is achieved. With the drill according to the invention, an increase in the total percussion drilling performance by up to 50% or more can be achieved in comparison with the known drills.

Further features of the invention emerge from the subclaims.

• Fig. 1 teilweise in Ansicht und teilweise im Axialschnitt einen Bohrer bekannter Ausführung,
• Fig. 2 in einer Darstellung entsprechend Fig. 1 eine Ausführungsform eines erfindungsgemäßen Bohrers,
• Fig. 3 in einer Darstellung entsprechend Fig. 1 eine weitere Ausführungsform eines erfindungsgemäßen Bohrers.

The invention is explained in more detail with reference to the drawing, in which a drill according to the prior art and two embodiments of the drill according to the invention are shown. Show it

• 1 partially in view and partially in axial section a drill of known design,
• 2 in a representation corresponding to FIG. 1, an embodiment of a drill according to the invention,
• Fig. 3 in a representation corresponding to FIG. 1, a further embodiment of a drill according to the invention.

In Fig. 1, a known rock drill of conventional design is shown for a better understanding of the invention. This drill has a shank 2 and a hollow drill bit 1 with a flat bottom 3 which is perpendicular to the drill axis A. The cutting ring of the hollow drill bit is formed by a hard metal cutting ring 5, but can also be fitted with hard metal teeth or be designed in another way for cutting. The drill is clamped in a hand drill and used for rotary drilling. The axially directed impact forces superimposed on the rotary movement of the drill act on the end face 4 of the drill shank 2. These impact impulses are transmitted via the drill shank 2 to the hollow drill bit 1 and from there into the cutting ring 5. The arrows P and p1 symbolize the impinging impulses that are transmitted in the material of the drill. In the drill according to FIG. 1, a large part of the impact energy is not passed on into the cutting ring, but rather emerges in the area of the flat crown bottom 3 as a sound wave, which is symbolized by the arrows p2. This part of the axially acting force is therefore lost for the impact machining, so that the drill has a low efficiency with regard to the impact performance.

2 and 3 show two embodiments of the rock drill according to the invention, which has a much better efficiency due to a special design of its interior. As shown in FIG. 2, the drill section 7a is hollow between the drill shaft and the cylindrical section 1a, so that the bottom 3a of the hollow drill bit is deepened and tapers downwards. It is thereby achieved that the impact pulses P are deflected in the transition region from the drill shaft 2a to the wall of the hollow drill bit in such a way that that the transmitted pulses p1 still contain the largest part of the impact energy. A significantly higher axial force therefore acts on the cutting ring 5a than in the known drill (FIG. 1). The crown base 3a is inclined in the axial plane at an angle to the drill axis A and runs obliquely in the axial section in the direction of the cylindrical wall 8a of the hollow drill bit. In order to achieve a particularly smooth transition from the drill shank 2a to the drill bit 1a and a soft deflection of the impact impulses, the crown base 3a is conical, the cone axis coinciding with the drill axis A. In addition, the bottom 3a runs parallel to the conical outer lateral surface of the drill section 7a forming the transition region, so that the wall in the region of the conical bottom 3a has an approximately constant thickness. The impact force acting on the end face 4a of the drill shaft 2a is deflected into the wall of the conical drill section 7a in the region of the cone tip, which is near the lower end 6a of the crown base 3a. Because of the inclined position of the crown base 3a, only a relatively small proportion of the impact energy is lost, while the major part reaches the cutting ring 5a via the section 7a and the subsequent hollow drill bit section formed by the cylindrical wall 8a. With this drill, an increase in the total percussion drilling performance of about 50% is achieved in comparison to the conventional design (FIG. 1). The wall thickness of the conical section 7a is sufficiently large to be able to transmit the forces occurring during impact drilling without the risk of breakage. The thickness of the wall need not be the same over the entire height of section 7a; it could, for example, also increase steadily in the direction of the drill shank.

In order to keep the material stress at the transition from the drill shaft 2a into the conical section 7a low and to ensure a low-loss deflection of the axial forces, the cone angle p of the crown base 3a should be less than approximately 130 °. In the case of a substantially larger cone angle, a large lever arm would act on the transition point to the shaft via the cylindrical hollow drill bit section 8a, so that, above all, the bending stress would be very great. The Kegelwinkelß should therefore preferably be only about 60 ° to about 90 °.

The inner surfaces 9a and 9a 'and the outer surfaces 10a and 10a' of the two sections 8a and 7a adjoin one another directly, so that there are no projections or shoulders at the transition between them which could lead to cracking as a result of a notch effect and thus to a risk of breakage. The two sections 7a and 8a have approximately the same wall thickness, which facilitates the manufacture of the drill. The cylindrical section 8a has a greater length in the axial direction of the drill than the conical section 7a. The crown base 3a is rounded at the deepest point 6a, so that there is no notch effect in this area either.

The diameter D of the drill shaft 2a is greater than the wall thickness d of the hollow drill bit, and the two dimensions are matched to one another so that the drill shaft 2a can absorb and transmit a high impact force and the hollow drill bit can safely absorb this force and the reaction forces. A favorable ratio arises here if the wall thickness d is approximately a quarter to a third of the shaft diameter D.

In the embodiment shown in Fig. 3, the drill is formed in two parts. The cylindrical section 8b is a separate part, which forms the hollow drill bit and is fastened to the conical section 7b, which in turn is formed in one piece with the drill shaft 2b. As a result, the cylindrical hollow drill bits can be exchangeable. The conical section 7b is thus a section of the drill shaft, but forms the bottom when the crown 8b is inserted. This section 7b has a cylindrical collar 11, the outer lateral surface 12 of which merges into the conical lateral surface 10b 'of the drill section 7b. In the area above the transition between the lateral surfaces 10b 'and 12, the conical section 7b has on the inside a shoulder 13 which has a support surface 14 lying at right angles to the drill axis A and a fitting surface 15 for the drill bit 1b lying in the direction of the drill axis. The cylindrical hollow drill bit 8b is supported in the axial direction on the support surface 14 and also lies with its outer lateral surface 10b on the mating surface 15 over the entire circumference. The cylindrical wall 8b of the hollow drill bit is thereby securely supported in the axial and radial directions on the conical drill section 7b. It can be firmly connected to the section 7b by gluing, soldering or in a similar manner, but also releasably with screws or the like. The height of the collar 11 measured in the direction of the drilling axis corresponds approximately to half the height of the cylindrical wall 8b of the hollow drill bit, which is therefore adequately secured in the radial direction. This also provides a relatively large mounting surface for the Bohr._krone 1b. The width of the support surface 14 corresponds approximately to the wall thickness of the cylindrical wall 8b, which thereby rests completely on the support surface 14 with its inner end face, so that the impact pulses p1 are undisturbed and completely introduced into the hollow core bit and the reaction forces are absorbed via the support surface 14.

The conical crown base 3b directly adjoins the support surface 14. A smooth transition from the cylindrical inner surface 9b to the crown base 3b is thereby achieved. Since the support surface 14 of the shoulder 13 is closer to the cutting ring 5b than the transition point between the outer circumferential surfaces 12 and 10b of the conical section 7b, the cylindrical collar 11 has a wall thickness which is sufficient for the intended purpose but not too great, which saves material becomes.

Because of the full-surface frontal support of the wall 8b on the shoulder surface 14, the wall of the conical section 7b is thicker than when the drill is made in one piece (cf. FIG. 2). Its thickness d2 is approximately twice the wall thickness d1 of the cylindrical drill bit and approximately half the shank diameter D.

The lower end 6a and 6b of the crown base 3a and 3b lies in both versions approximately at the height of the upper shaft end; 3, the bottom end 6b is slightly higher than the plane defining the shaft end, which results in a higher strength. The position of the lower bottom end 6a or 6b in the illustrated axial section results in a fork-like branching of the shaft into the conical section 7a or 7b and is essential for the largely lossless introduction of force from the shaft into the conical section.

Claims (13)

1. Drill, in particular rock drill, for rotary impact drilling, with a shank and a hollow drill bit, which has a cutting ring on the end face on its cylindrical wall, characterized in that the drill in the transition region between the shank (2a; 2b) and the cylindrical wall (8a ; 8b) of the hollow drill bit (1a; 1b) is designed as a hollow drill section (7a; 7b) which forms a bottom (3a; 3b) of the hollow drill bit (1a; 1b) that tapers towards the shaft (2a; 2b). 2. Drill according to claim 1, characterized in that the crown base (3a; 3b) is conical. 3. Drill according to Claim 1 or 2, characterized in that the hollow drill section (7a; 7b) forming the transition region between the shank (2a; 2b) and the cylindrical wall (8a; 8b) of the hollow drill bit (1a; 1b) its entire height is about the same wall thickness. 4. Drill according to one of claims 1 to 3, characterized in that the opening angle (β) of the crown base (3a; 3b) is less than about 130 °, preferably about 60 ° to about 90 °. 5. Drill according to one of claims 1 to 4, characterized in that the cylindrical wall (8a) of the hollow drill bit (1a) has approximately the same thickness as the wall of the hollow drill section (7a). 6. Drill according to one of claims 1 to 5, characterized in that the crown base (3a; 3b) is rounded at its lower end. 7. Drill according to one of claims 1 to 6, characterized in that the lower end of the crown base (3a; 3b) is approximately at the level of the upper end of the shaft. 8. Drill according to one of claims 1 to 7, characterized in that the hollow drill bit (1b) is inserted as a separate part in the hollow drill section (7b). 9. Drill according to claim 8, characterized in that the hollow drill bit (1b) is cylindrical and open at the lower end. 10. Drill according to claim 9, characterized in that the transition region forming hollow drill section (7b) is integrally formed with the drill shaft (2b) and an inner support surface (14) for the lower end face of the drill axis (A) lying perpendicular to the drill axis inserted hollow core bit (1b). 11. Drill according to one of claims 8 to 10, characterized in that the hollow drill section (7b) has a mating surface (15) for the radial support of the hollow drill bit (1b). 12. Drill according to claims 10 and 11, characterized in that the support surface (14) and the mating surface (15) are formed by a shoulder (13) which has an annular collar (11) for receiving the hollow drill bit (1b). 13. Drill according to one of claims 8 to 12, characterized in that the hollow drill bit (1b) is releasably attached to the hollow drill section (7b).

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