JPH0513451Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to an end mill suitable for processing hard materials such as hardened steel and chilled cast iron, and difficult-to-cut materials such as heat-resistant alloys.

(Prior art) Conventionally, this type of end mill has, for example,
Those disclosed in Japanese Patent Application Laid-open No. 56-95528 and Japanese Utility Model Application Publication No. 60-149712 are known. The former has hard abrasive grains such as diamond abrasive grains electrodeposited on the margin of the outer peripheral edge of a right-hand edge with a super left-handed twist. In the latter case, the second corner of the bottom edge of the end mill has a zero degree angle, and high-hardness abrasive grains are attached to this second corner. Therefore, the latter method is applied in a method such as a face milling cutter, and is not applied to a processing method mainly using a peripheral cutting edge.

(Problem that the invention aims to solve) However, when using the conventional end mill mentioned above to cut high-hardness materials, heat-resistant alloys, etc. mainly with the peripheral cutting edge, However, there was a problem in that the margin formed on the flank side of the outer periphery was severely worn, resulting in a short life of the outer cutting edge.

For this reason, the present invention aims to improve the short life of the peripheral cutting edge when cutting high-hardness materials, heat-resistant alloys, etc. mainly using the peripheral cutting edge.

(Means for Solving the Problems) The end mill of the present invention is configured so that, in addition to normal cutting by the outer peripheral cutting edge, a minute cutting surface is formed on the outer peripheral flank side at a distance from the outer peripheral cutting edge. be. This micro-cut surface is made of diamond,
It is constructed by electrodepositing superabrasive grains such as cubic boron nitride.

(Function) The end mill of the present invention performs normal cutting with the bottom edge and the outer edge, and at least on the outer flank side, the micro-cutting surface is electrodeposited with superabrasive grains such as diamond or cubic boron nitride. By configuring this, micro-cutting can be performed at the same time as cutting by the outer peripheral edge.

(Example) Hereinafter, an example of the end mill of the present invention will be described with reference to the drawings.

1 and 2, reference numeral 1 indicates an end mill, and the figure shows a four-blade square end mill made of cemented carbide, cermet, ceramics, high-speed steel, or the like.

A flute groove 3 having a twist in the axial direction is formed in the outer peripheral portion of the tool body 2, and a land portion 6 having an outer peripheral edge 4 and an outer peripheral relief surface 5 is formed accordingly. In this case, the twist may be either right-handed or left-handed, but when applied to processing high-hardness materials, heat-resistant alloys, etc.
A large twist angle, for example, is appropriately selected within the range of ±15° to ±70°. Furthermore, when applied to processing laminates, etc., a small helix angle of ±15° or less is selected.

Further, a bottom edge 7 and a flank are formed in the direction of the shaft end surface of the tool body 2.

Therefore, the end mill 1 of the present invention has at least the outer peripheral flank 5 as shown in FIG.
On the side, a minute cutting surface 8 is formed at a rear position of the outer peripheral edge 4 with reference to the rotation direction. This micro-cut surface 8 is one on which superabrasive grains made of diamond, cubic boron nitride, etc. are electrodeposited with Ni or the like. Therefore, it is preferable that the superabrasive be coarser than #400. This is different from coatings such as TiC and TiN, which are used to improve wear resistance and are found in conventional carbide end mills. This is because, in the present invention, in addition to normal cutting by the outer peripheral edge 4 and bottom edge of the end mill 1, cutting is also performed by the minute cutting surface 8 based on the trochoidal curve 10. Therefore, it is different from electrodeposited grindstones and the like. Note that the trochoid curve 10 is a rotation locus of the cutting edge formed when the end mill rotates while being fed, as shown in FIG.

Further, the outer peripheral cutting edge 4 can be round honed or angular honed to strengthen the cutting edge.
This is because when cutting high-hardness materials with a general end mill, slippage occurs significantly in areas where the actual cutting thickness is small, but with the present invention,
This can be applied because the micro-cutting surface 8 performs micro-cutting and suppresses the above-mentioned slipping phenomenon.

Further, the micro-cutting surface 8 of the present invention improves the finished surface by micro-cutting when a so-called zero cassette is used in which the depth of cut in the radial direction is zero. It is usually desirable that the micro-cutting surface 8 having such a function be provided on all the outer circumferential flank surfaces 5, but in an end mill with two or more multiple blades, the micro-cutting surface 8 may be formed on at least one of them depending on the cutting conditions. do it.

The outer peripheral flank 5 protrudes from the land portion 6 in the radial direction, but its outer edge may be eccentric, straight, or concave. can. Moreover, the micro-cutting surface 8 can also be formed on the flank surface on the bottom blade side.

(Effect of the invention) As explained above, the present invention has an end mill 1
At least on the peripheral flank 5 side, there is a micro-cutting surface 8 on which superabrasive grains are electrodeposited at a position spaced apart from the peripheral cutting edge 4.
Since this structure is configured, it is possible to perform micro-cutting using the micro-cutting surface 8 in addition to normal cutting, thereby making it possible to perform so-called complex cutting.

As a result, it has the advantage of being applicable to machining difficult-to-cut materials such as high-hardness materials and heat-resistant alloys.

[Brief explanation of the drawing]

Fig. 1 is a front view of essential parts showing an embodiment of the end mill of the present invention, Fig. 2 is a cross-sectional view, and Fig. 3 is a
FIG. 3 is a partially enlarged sectional view of the cutting edge portion. 1...End mill, 2...Tool body, 3...Flute groove, 4...Outer peripheral edge, 5...Outer peripheral flank,
6...Land part, 8...Minute cutting surface.

Claims (1)

[Claims for Utility Model Registration] An end mill in which a land portion 6 having a flute groove 3, an outer cutting edge 4, and an outer circumferential relief surface 5 is formed on the outer peripheral side of a rod-shaped tool body 2, On at least one of the peripheral flanks 5, superabrasive grains made of diamond, cubic boron nitride, etc. are electrodeposited at a position rearward of the peripheral cutting edge 4 with reference to the rotation direction, and superabrasive grains made of diamond, cubic boron nitride, etc. are electrodeposited in a spaced apart electrodeposited layer. Micro-cutting surface 8
An end mill characterized by comprising: