SU1144800A1 - Drill - Google Patents

Abstract

1. Drill equipped with a carbide cutting insert, characterized in that, in order to increase durability by reducing wear of the lintel, the insert is made cylindrical from a polycrystal of synthetic superhard material, the ratio of the drill diameter to the insert diameter being 6-9. 2. The drill according to claim 1, wherein the cutting part has a wear-resistant reinforcement coating in the form of spitting of a refractory metal nitride.

Description

The invention relates to metalworking and can be used in the manufacture of twist drills.

Spiral drills are known that are equipped with carbide inserts that form a cutting edge with a higher hardness than the material of the rest of the drill. Insert fixed by soldering Ct

However, when drilling with small diameter drills (less than 16 mm) with difficult to handle a lx materials, there is an increased wear of the central part of the cutting edge, i.e. jumper drills while maintaining the cutting ability of the periphery, which is a consequence of insufficient hardness of the central part of the insert.

The purpose of the invention is to increase the durability of the drill by reducing wear of the web.

This goal is achieved by the fact that in a drill equipped with a carbide cutting insert, the latter is made with a crystal shape of a polycrystalline synthetic superhard material, and the ratio of the drill diameter to the insert diameter is.

The cutting part has a wear-resistant hardened cade coating in the form of a refractory metal nitride film.

Superhard material, for example synthetic polycrystal of boron nitride or diamond, has a high hardness, which increases the resistance of the drill web that is subjected to the greatest degree. This increases the durability of the drill as a whole.

The most reliable method of fastening the core of a superhard material is soft soldering or hardfooom shine. Soft brazing requires the preliminary metallization of superhard material and the use of expensive silver solder.

As a solid solder, copper-titanium solder is most effective, providing soldering in vacuum without preliminary metallization and superhard material and not requiring the use of precious metals. The titanium content is 25-30 wt.%. It is possible to add other elements, for example, tin or yttrium, in the amount of 2-3 wt.%.

Polycrystals of boron nitride are used for drilling steel and the quality of the core, and for drilling non-ferrous materials (non-ferrous metals and alloys, plastics) the core is made of synthetic diamond polycrystal. The ratio of the diameter of the drill to the diameter of the insert within 6-9 is chosen to secure the polycrystal securely in the core of the drill.

When drilling high-strength materials, the solder layer may be destroyed in the gap between the superhard and the main material of the drill. In order to increase durability in this case, the drill has a reinforcing coating of a refractory metal nitride (TiN; MoN).

FIG. t shows a drill, side view with a local section along the axis; in fig. 2 is a section A-A in FIG. one.

The drill consists of a main part 1, a cylindrical core 2 fixed with solder 3, and a coating of the cutting part 4.

Example 1. For drilling of structural steels, a drill from high-speed steel has a polycrystalline insert of solid boron nitride of cylindrical shape, which is fixed by soldering with copper-titanium solder. For drilling materials, do not contain | iron (nonferrous metals and alloys, plastics), the insert is made of polycrystal of synthetic diamond.

EXAMPLE 2: For drilling in hard-to-draw steels, a solid carbide drill has an insert of polycrystal of solid boron nitride, which is fixed by soldering. If the material being processed does not interact with the diamond during cutting, the insert is made of polycrystalline synthetic diamond.

EXAMPLE 3. To increase the resistance of a drill with an insert in the form of a core of superhard material, its cutting part is applied by vacuum ion condensation using a wear-resistant reinforcement coating in the form of a film of a refractory metal nitride (titanium, molybdenum or zirconium) 2 -10 microns.

Increasing the strength of the drill web by using an insert in the form of a core of superhard material increases durability by 6-8 times in comparison with the known drills used in the same operation, and for drills with wear-resistant reinforcement: coating - by 10-15 times. ;

Claims (2)

1. A DRILL equipped with a carbide cutting insert, characterized in that, in order to increase durability by reducing jumper wear, the insert is made of a cylindrical shape made of polycrystalline synthetic superhard material, and the ratio of the diameter of the drill to the diameter of the insert is 6–9. 2. The drill according to claim 1, with the fact that the cutting part has a wear-resistant hardening coating in the form of a film of refractory metal nitride. 1 1144800 1