EP0280835A1 - Hollow drill tool - Google Patents

Abstract

The hollow drill tool (1) has a hollow-cylindrical support body (2) and cutting segments (4) which consist of an embedding material and a diamond grain (9) held in the latter. The surface layer (7) of the cutting segments (4) which is remote from the axis of the support body (2) has a higher concentration of diamond grain compared with the remaining area of the cutting segments (4). This guarantees the production of a large number of drill holes of high diametral accuracy. <IMAGE>

Description

The invention relates to a hollow drill with a hollow cylindrical carrier body, on the drilling direction side open end of which the end face and the circumferential contour of the carrier body projecting cutting segments containing diamond grain are arranged.

A hollow drill with cutting segments containing diamond grain is known from AT-PS 373 196. The cutting segments sit on the end face of a hollow cylindrical support body and have an end face pointing in the direction of drilling and an outer contour curved in a circular arc in the axial projection of the hollow drill and concentrically projecting over the circumferential contour of the support body. The diamond grain, which is distributed in an embedding material, is not only inside the cutting segments, but is partly exposed to the end face and the outer contour.

When working with the hollow drill, the cutting segments with the end face remove material from the material to be machined, for example concrete, natural stone, brick, to create a borehole. The outer contour of the cutting segments slides along the wall of the borehole that is being created, thereby causing the hollow drill bit to be guided laterally. As a result of wear and tear, this not only results in axial shortening, but also in radial cutting of the cutting segments from the outer contour. The radial cutting of the cutting segments takes place to such a high degree that after just a few drilling operations, only holes with a greatly reduced diameter are created.

This dimensional deviation is irrelevant if the boreholes are only to be used, for example, to pass through pipes or, by lining up such boreholes, to produce an opening. In contrast, boreholes with such a reduced diameter are for the recording Mechanical anchors are unsuitable because the anchors are difficult to insert into the drill holes or cannot be inserted at all. However, it is also not possible to use hollow drills with a larger bore diameter when new to circumvent this problem, since this would initially result in oversized drill holes, which in turn would affect the anchorage value of the dowels.

To ensure good insertability and high anchoring values for dowels, the drill holes intended to receive them must therefore only be subject to slight fluctuations in diameter. So the acceptable deviation from the ideal diameter is in the range of tenths of a millimeter. Approximately half of this deviation alone takes up the manufacturing tolerances of the hollow drill, so that there is only a very small margin available for the permissible radial removal of the cutting segments.

The invention has for its object to provide a hollow drill with cutting segments containing diamond grain, with which a large number of holes can be made with high diameter accuracy.

According to the invention, the object is achieved in that the cutting segments have a surface layer which extends concentrically to the circumferential contour of the carrier body and has a higher diamond grain concentration than the remaining area of the cutting segments.

The surface layer with an increased diamond grain concentration extends at least over a part of the outer contour of the cutting segments that projects beyond the peripheral contour of the carrier body. Due to the higher diamond grain concentration, the wear resistance of the surface layer is significantly higher than the wear resistance of the remaining area of the cutting segments. This leads to more extensive radial dimensional accuracy of the cutting segments, so that a large number of drill holes with high diameter accuracy can be produced.

Particularly high wear resistance is preferably achieved in that the extent of the surface layer measured in the circumferential direction corresponds to that of the cutting segments.

To increase the wear resistance, the extent of the surface layer measured in the axial direction of the drill also corresponds to that of the cutting segments according to a further proposal of the invention.

In a further development of the invention, the extent of the surface layer measured in the axial direction of the drill exceeds the extent of the cutting segments measured in the axial direction and projecting beyond the end face of the carrier body. This design is particularly suitable for workpieces with high strength to improve the radial dimensional accuracy of the cutting segments.

The section of the surface layer set back relative to the end face of the carrier body can be fixed on the circumferential contour of the carrier body or can be supported and held by an extension connected to the remaining area of the cutting segments. Such a section of the surface layer, which adjoins the end face of the carrier body against the direction of drilling, makes the surface layer serving for lateral guidance of the hollow drill overall more extensive, which results in a possibility of controlling the required diamond grain concentration in the surface layer as a whole. Above all, the recessed section of the surface layer can ensure high radial dimensional accuracy of the cutting segments up to the complete axial shortening of the part of the cutting segments projecting beyond the end face of the carrier body.

The diamond grain concentration in the surface layer preferably corresponds to two to five times the diamond grain concentration in the remaining region of the cutting segments. The higher the strength of the processed material, the higher the diamond grain concentration in the range specified above is chosen.

The surface layer advantageously has a thickness of 0.2 to 1 mm. In addition to sufficient wear resistance of the surface layer, this ensures that the surface layer together with the end face of the cutting segments is gradually removed axially without the surface layer adversely affecting the drilling behavior.

• Fig. 1 einen Hohlbohrer in perspektivischer Darstellung;
• Fig. 2 eine vergrösserte Detail-Ansicht auf die Stirnseite des Hohlbohrers gemäss Fig. 1.

The invention is explained below with reference to a drawing which shows an embodiment. Show it:

• Figure 1 shows a hollow drill in a perspective view.
• FIG. 2 shows an enlarged detail view of the end face of the hollow drill according to FIG. 1.

The hollow drill, designated as a whole by 1, consists of a hollow cylindrical carrier body 2 with a drive shaft 3 molded onto the end facing away from the drilling direction and project radially beyond the circumferential contour of the carrier body 2.

The cutting segments 4 have an end face 6 pointing in the drilling direction and a surface layer 7 which extends concentrically to the circumferential contour of the carrier body 2 and which also extends counter to the drilling direction and then to the end face 5 along the circumferential contour of the carrier body 2 with a section 8. The Cutting segments 4 consist of an embedding material, for example cobalt with metallic additives such as copper, tin, zinc, tungsten, in which diamond grain 9 is embedded in a spatially distributed manner. In the surface layer 7, the diamond grain concentration is two to five times the remaining area of the cutting segments 4, as shown in FIG. 2. The thickness of the surface layer 7 is 0.2 to 1 mm.

As a result of the greater diamond grain concentration in the surface layer 7, high radial wear resistance of the cutting segments 4 is achieved, so that a large number of drill holes of high diameter accuracy can be produced with the hollow drill 1.

Claims (6)

1. Hollow drill (1) with a hollow cylindrical carrier body (2), on the drilling direction side open end of which the end face and the peripheral contour of the carrier body (2) projecting, diamond grain (9) containing cutting segments (4) are arranged, characterized in that the cutting segments ( 4) have a surface layer (7) which extends concentrically to the circumferential contour of the carrier body (2) and which has a higher diamond grain concentration than the rest of the cutting segments (4). 2. Hollow drill according to claim 1, characterized in that the extent of the surface layer (7) measured in the circumferential direction corresponds to that of the cutting segments (4). 3. Hollow drill according to claim 1 or 2, characterized in that the extent of the surface layer (7) measured in the axial direction of the drill (1) corresponds to that of the cutting segments (4). 4. Hollow drill according to claim 1 or 2, characterized in that the extension of the surface layer (7) measured in the axial direction of the drill exceeds the extension of the cutting segments (4) which is measured in the axial direction and which projects over the end face (5) of the carrier body (2). 5. Hollow drill according to one of claims 1 to 4, characterized in that the diamond grain concentration in the surface layer (7) corresponds to two to five times the diamond grain concentration in the remaining region of the cutting segments (4). 6. Hollow drill according to one of claims 1 to 5, characterized in that the surface layer (7) has a thickness of 0.2 to 1 mm.

Images