DE2358447B1 - Rotary percussive drill with removal grooves - has grooves pitched at forty degrees specified base to shaft stay ratio - Google Patents

Abstract

Rotary percussive drill up to 12 mm diameter consists of a bit with drillings removal grooves cut into the shaft so that their respective base areas run axi-parallel and lead over into the flanks through a rounded part smaller in radius than the total depth of the groove itself. The ratio of the groove base width to the spine width on the guide stays forming part of the drill shaft is 2:1 to 5:1, and the ratio of the groove depth to the rated diameter is 0.12 for the smallest diameter rising to 0.25v for the largest. Groove base width should rise steadily but by a small amount from the bit end to the chuck end, as compared with the spine width of the stays which decreases correspondingly.

Description

The invention relates to a rock drill up to a maximum of 12 mm nominal diameter for rotary percussion drills, with a drill bit and several in the Drill shank incised drill dust grooves, the respective base area of which is essentially axially parallel runs and is provided with fillets to their adjacent lateral flanks, the radius of which is smaller than the groove depth.

Drills of this type with a large nominal diameter, from around 14 mm, and a correspondingly small pitch around 35 ° are known (DAS 20 59 232).

It is also known for drills with similarly large nominal diameters and the pitch mentioned (Swiss Patent 5 25 753), the remaining parts of the drill jacket surface between the discharge grooves to avoid wall friction as narrow guide webs.

In a known rock drill (German patent 8 32 379) with only one drill dust groove Due to the relatively large drill dust flute widths, there are no problems in removing the accruing drilling dust, if the drill is not intended for use on high-performance drilling machines is used. However, the two-thread version of the same drill, which is also known, is different to evaluate whose drill dust grooves are relatively narrow and strongly rounded towards the flanks, so that its use on high-performance drilling machines is not possible.

In order to achieve the high conveying capacity of the cuttings flutes aimed at with the known drills with large diameters To be able to achieve also for drills with smaller diameters, numerous tests were necessary, varying the most important drill data. These attempts had the goal of creating small diameter drills that could be used on modern, powerful Rotary percussion drills are unreservedly eligible after the known Drills of small diameter has shown that their drill dust capacity does not match the drilling progress possible with high-performance impact drills is fair. But if more drill dust is removed from the drill cutting edge than the drill dust grooves convey away can, there is a drill dust jam in the drill dust grooves. The consequences are a slowdown the drilling progress, possibly the drilling machine standstill, heating, strong torsional load on the drill, possibly broken drill, deflagration of the drill dust when withdrawing the drill.

Only on the basis of a long series of tests was it possible, taking into account different criteria, to find out that combination of such criteria, through their application in an optimal way, the Task is solved by a sharp and wear-resistant drill bit and strong axial Impact of the machine and based on drills with a nominal diameter of no more than 12 mm remove any drilling dust without jamming, while at the same time achieving a significant increase in performance.

A drill improved according to the invention is characterized in that

the pitch angle of each drill dust groove = 40 °, the ratio of the drill dust groove width to the back width of the guide webs of the drill shank 2: 1 to 5: 1 and
the ratio of the groove width to the nominal diameter is 0.12 for the smallest to 0.25 for the largest nominal diameter.

The ratio of drill dust flute width to back width of 2: 1 is with regard to the desired enlargement the drilling dust conveying capacity is not yet optimal, on the other hand with the ratio value 5: 1 and on top of this, the risk of the narrow guide webs being worn too quickly. Are particularly advantageous therefore intermediate values. The determination of these dimensions is very important to achieve the largest possible cross-section of the drill dust grooves, in addition to the groove depth Groove width is the decisive factor.

Since the increased impact performance of modern drilling machines place particular demands on the drill in the area of the cutting end and the soldering of the cutting edge, it is important that each drill dust groove in the area of the cutting end has a groove depth reduced by about 1/3.
This avoids weakening the cutting end in this critical area. According to a further proposal of the invention it is provided that the drill dust flute width from the cutting end to the clamping end of the drill steadily increases slightly, wherein

the back width of the guide bars decreases accordingly. This measure takes place in the drilling ^ ehlnut ascending drill dust an increasingly larger one Space, whereby the loose stratification of the cuttings is maintained as the conveying path increases can be.

To improve the stability of the drill it can be provided that the core of the drill shaft over the entire length or part of the length of the drill shaft in the direction from the head end to the clamping end of the drill gradually increases in diameter, with the depth of the groove decreasing accordingly. When realizing this feature, the dimensioning of the drill dust flute width must be taken into account: that their cross-section remains the same overall or extends from the cutting end to the clamping end of the drill steadily increased slightly.

Details of the invention can be found in the description. In the drawing shows

F i g. 1 shows a side view of a drill and FIG. 2 shows an axial partial section through the drill.

The F i g. 2 shows the in FIG. 1 shown drill in an approximately three times enlarged profile section. The drill 1 is shown in FIG. 1 shown shortened in length. In the upper part of FIG. 1 shows the clamping end 2 and the cutting end 3 at the lower end. In addition, the drilling dust grooves 4a and Ab increasing at the pitch angle δ can be seen; So it is a two-start drill shaft. The drill cutting edge 5, which is made of a particularly hard and wear-resistant material, is soldered into the cutting end of the drill shank. In the region of the length t of the drill containing the cutting edge, the depth of the milling dust flutes is reduced by approximately 1/3. The length t is preferably 1 to 2 times the cutting insert height.

The dimensions of the drill according to the illustrated embodiment are each approximately: nominal diameter D = 12 mm; Shaft diameter d = 11 mm; Slope δ = 45 °; mean groove width η = 11 mm; mean web width / = 2.5 mm; Groove depth T = 2.3 mm; Flank radius R = 1 mm.

In FIG. 2, the tapering of the drill core in the direction of the cutting end is also drawn in, the core running conically. The cone angle γ is about 1 ° to 2 °. As a result of the slightly conical design of the drill core, there is a slight increase in the groove depth Γ from the clamping end to the cutting edge of the drill. In the reverse direction, namely, from the head to the clamping end of the drill, the groove width increases η gradually such that m is greater than m, and m is greater than m. The same applies for the web width, the reversed towards increasingly decreases the clamping end from the head end, that is, / 3 is smaller than ή and h is smaller than h.

1 sheet of drawings

Claims (5)

Patent claims: 1. Rock drill up to a maximum of 12 mm nominal diameter for rotary percussion drills, with a drill bit and several drill dust flutes cut into the drill shank, their respective Base runs essentially axially parallel and with fillets to their adjoining lateral flanks is provided, the radius of which is smaller than the groove depth, characterized in that that the pitch angle (ό) of each drill dust groove ^ .40 °, the ratio of the drill dust flute width (n) to the back width (f) of the guide webs of the drill shank 2: 1 to 5: 1 and
the ratio of the groove depth (T) to the nominal diameter (D) is 0.12 for the smallest to 0.25 for the largest nominal diameter. 2. Rock drill according to claim 1, characterized in that each drill dust groove (4a, 4b) in the region (t) of the drill bit has a groove depth (T) reduced by approximately V3. 3. Rock drill according to claim 1 or 2, characterized in that the drill dust groove width (s) from the cutting end (3) to the clamping end (2) of the drill (1) steadily increases slightly and the back width (f) of the guide webs decreases accordingly. 4. Rock drill according to one of claims 1 to 3, characterized in that the core of the Drill shank over the entire length or part of the length of the drill shank in the direction of Cutting end (3) to the clamping end (2) of the drill (1) gradually increases in diameter and the groove depth (T) decreases accordingly. 5. Rock drill according to claims 3 and 4, characterized in that the drill dust flute cross-section from the cutting end (3) to the clamping end (2) of the drill (1) steadily increases slightly.