JPH0561047B2 - - Google Patents

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to a ball end mill, and particularly to a ball end mill whose cutting edge has been improved to have a shape suitable for finish cutting.

[Conventional technology]

As shown in FIG. 9, the use of a ball end mill is essential for machining curved surfaces of molds and the like. The cutting edge shape of the ball end mill is configured to form a spherical surface by rotating.
Figure 8 shows the cutting edge of a generally shaped ball end mill. Normally, the second surface 12 of the rounded cutting edge (cutting edge for spherical cutting) 11 at the tip is the sixth
As shown in the figure, they intersect and connect at the tip of the end mill, and a cutting edge is not formed at that portion, but a tip core thickness portion 13, that is, a portion similar to a chisel portion of a drill is formed. This tip core thickness portion 13 is
Although it is a convex curved surface, it is slightly more concave than a spherical surface, making it a nearly flat curved surface, and has the disadvantage that it does not form part of a true spherical surface. This drawback can be compensated for by making the cutting edge shape such that the width t of the tip core thickness portion 13 is 0, but in that case, the continuous portion of both cutting edges is The top of the tip of the tool is a point that makes contact with the workpiece at one point, and is a place with extremely poor wear resistance. Therefore, due to wear during use, the cutting edge in that area is quickly worn out, resulting in a discontinuous part of the cutting edge (a space between the two cutting edges opens up, creating a gap).
In each of these figures, 14 is the third surface, 15 is the gear, and 16 is the outer peripheral cutting edge. Therefore, as a solution to the above problems,
As shown in FIGS. 10 and 11, continuous portions of both cutting edges are shifted from the top of the tip, and a rounded cutting edge is formed from the long blade 21 passing through the top of the axis and the short blade 22 of the remaining portion. It is effective to do so. However, in the notch 23 where the long blade 21 and the short blade 22 are separated, an edge-shaped cutting edge corner portion 24 is formed at the end of the long blade 21 and the short blade 22. This edge-shaped corner portion 24 is formed when the ball end mill rotates theoretically, that is, when it rotates around the rotation axis without any twist or resistance.
Since the long blades 21 completely overlap, no streak-like cutting marks are left on the cutting surface. However, it is unlikely that an actual tool is completely free of twisting, and furthermore, when feed is applied during actual cutting, deflection and dynamic twisting occur due to cutting resistance. Therefore, the edge-shaped corner portion 24 as described above does not completely overlap with the long blade 21 during actual cutting, and the cutting trace becomes a "streak". Furthermore, if chipping occurs at the corner portion 24, the adverse effects will be even more significant, and in extreme cases, welding will occur at the chipped portion.

[Problem to be solved by the invention]

The reason why the rounded cutting edge is formed by a combination of a long blade and a short blade is to improve cutting accuracy by maintaining the cutting blade shape that forms a spherical surface through rotation. High-precision mold parts such as molds require a polishing process after machining, but if the accuracy during machining is poor, the time required for the finishing process will be longer. How to shorten the time depends on how to improve the accuracy of machining using a ball end mill. Therefore, an object of the present invention is to eliminate the adverse effects caused by the corners of each cutting edge of a ball end mill having a rounded cutting edge consisting of a long blade and a short blade as described above, and to improve accuracy during machining. Our goal is to provide a ball end mill that can maximize the quality of our products.

[Means to solve the problem]

The ball end mill according to the present invention solves the problems of the prior art as described above and has the following configuration in order to achieve the object. That is, in a ball end mill in which a rounded cutting edge that performs spherical cutting consists of one long blade that passes through the rotation center axis and at least one short blade, the notch that separates the long blade and the short blade is These ridge lines transition from the cutting edge lines of the long blade and short blade to the ridge line portion of the notch by forming a chamfer with a smoothly continuous curved surface from the second surface of each of the long blade and short blade. is formed by a smoothly continuous curve, and the radial rake angle of the long blade and short blade with respect to the center of the spherical surface, that is, the point on the rotation axis of the ball end mill is the center of curvature of the rounded cutting edge. , and one point on the rounded cutting edge, in the cross section in the direction perpendicular to this cutting edge (normal direction), passing through the center of curvature of this rounded cutting edge and one point on the rounded cutting edge The angle formed by the rake face at the point on the rounded cutting edge with respect to the straight line is -15°
The angle is set to 0° or more.

[Action and effect of the invention]

In the ball end mill according to the present invention, the apex on the spherical surface obtained as a rotating body is located at one point on the cutting edge line of the long blade, thereby ensuring a highly accurate spherical surface up to the apex of the axis of the tool. In particular, the ability to provide a chip pocket up to the top of the shaft improves chip evacuation and machinability in that area. In addition, these ridge lines that transition from the cutting edge lines of the long blade and short blade to the ridge line of the notch are chamfered with smoothly continuous curves, so the transition from the long blade and short blade to the notch is chamfered. No edge-like corner portions are formed as in prior art ball end mills. Therefore, the cutting edge line, which consists of smoothly continuous curves at the transition from the long and short blades to the notch, cuts a smoothly continuous curved surface and leaves no trace of "streaks" on the finished surface. Furthermore, the chamfering prevents chipping. By setting the above-mentioned rake angle to -15° or more and 0° or less, cutting resistance is generated in the compressive direction to the finished surface, improving the finished surface roughness. In particular, the dead point on the cutting edge on the axis of rotation, where the cutting speed is 0, is the weakest against thrust resistance.
This is a location where chipping is likely to occur, but the strength against thrust resistance in this region is significantly improved. However, if the rake angle is made excessively negative, cutting resistance increases and peel cutting is induced, so it is preferable to set the limit to −15°. In most normal ball end mills, the rake angle is a positive value, but the ball end mill of the present invention will not cause unnecessarily large cutting force if it is used only for finishing cutting (light cutting). Rather, by increasing the rigidity of the cutting edge, the effect of preventing microchipping of the cutting edge can be obtained. In particular, by setting the rake angle of the cutting edge to a negative value at the top of the axis of the tool, the effect of improving the strength of the cutting edge in this area and preventing chipping is remarkable. Note that this rake angle in conventional ball end mills is usually set to about 6° to 15° in order to improve cutting performance so that a certain amount of cut can be secured.

【Example】

The following describes a preferred embodiment of the present invention.
This will be explained with reference to the drawings to FIG. Fig. 1 is a diagram showing the shape of the cutting edge of the ball end mill of this embodiment as viewed from the tip of the cutting blade in the axial direction, Fig. 2 is a diagram seen from the side, and Fig. 3 is the same as in Fig. 2. FIG. 4 is a cross-sectional view showing a portion of FIG. 2 on an enlarged scale. The ball end mill of this embodiment has two blades, one long blade 1 and one short blade 2.
The notch 3 between the long blade 1 and the short blade 2 has a curved surface with radii of curvature R ₁ and R ₂ at the portion corresponding to the corner of the cutting blade, as clearly shown in Fig. 4. It is chamfered. In the figure, the radius of curvature R ₁ is the chamfer on the short blade side, R ₂ is the chamfer on the long blade side, P ₁ , P ₂
are their centers of curvature. In the figure, R is the radius of curvature of the spherical surface formed by the rotation of the rounded cutting edge, and P is the center of curvature. The second surfaces 4 and 5 of the long blade 1 and the short blade 2 and the curved surfaces of each chamfer have a common tangent at the transition point, and are smoothly continuous with each other, with no ridge line formed between them.
In FIG. 4, the transition point on the long blade side is located on the rotation center axis 6 of the ball end mill, but the transition point must not be formed beyond this on the long blade side. In Fig. 3, short blade 2 is taken as an example, and any one point of the short blade 2 is taken as an example.
For C _p , the rake angle θ in the radial direction from the center of curvature P of the spherical surface is shown. This radial direction rake angle θ is determined by taking a cross section of the ball end mill on a plane passing through the center of curvature point P and point C _p and in the normal direction of the short blade 2 at point C _p , and in this cross section, point P It is given by the angle formed by the rake face 7 of the short blade 2 with respect to the straight line passing through and point C _p . In this example, a negative rake angle of -15° is provided. Using the ball end mill of the present invention having the above configuration, finishing cutting was performed on a workpiece having the shape shown in Fig. 5, and the finished surface roughness was tested. As a result, R _nax was 2 μm or less. An extremely good finished surface was obtained. ●Ball end mill: Spherical radius...5mm, diameter...10
mm, blade length...15mm, total length...70mm, handle diameter...10mm, material...Cemented carbide + TiN coating, type...
Solid type ● Work material: SKD61 (HRC40), a = 100 mm, b = 20 mm, c = 75 mm, d = 30 mm, e = 25 mm, r = 25 mm, α = 45° ● Cutting conditions: rotation speed...2200 rpm, feed …300mm/
min, depth of cut (Z-axis direction)…0.1mm, pick feed (Y-axis direction)…0.07mm, milling machine used…NC milling machine (spindle motor 3.7kW/
5.5kW) The above explanation uses a two-flute solid type with a coating on cemented carbide as a model, but other materials include high-speed tool steel, as well as cermets and CBN (hexagonal type) for higher speeds. Materials commonly used for tools such as boron nitride (boron nitride) or diamond sintered bodies can be used, and multi-edged tools with three or more blades are possible. In that case, only one blade will be long and the rest will be short blades. In addition to the solid type, brazed type and throw-away type are also available.

[Brief explanation of drawings]

Fig. 1 is a diagram showing the cutting edge shape of the ball end mill of this embodiment as viewed from the cutting edge tip side in the axial direction, Fig. 2 is a side view of Fig. 4 is an enlarged sectional view of the part shown in FIG. 2, and FIG. 5 is a model of the workpiece that was subjected to a cutting test using the ball end mill of this example. Figure 6 is a diagram showing the cutting edge shape of a conventional general ball end mill viewed from the tip of the cutting edge in the axial direction.
Figure 8 is a side view of Figure 6, Figure 9 is a diagram showing the machining situation with a general ball end mill, and Figure 10 is a diagram showing the machining situation with a general ball end mill. A diagram showing the cutting edge shape of a conventional ball end mill viewed from the tip of the cutting edge toward the axial direction.
FIG. 11 is a side view of FIG. 10. 1...Long blade, 2...Short blade, 3...Notch, 4,
5...Second surface, 6...Rotation center axis, 7...Rake face, P...Curvature center point of rounded cutting edge, C _p ...
Any one point on the rounded cutting edge.

Claims (1)

[Scope of Claims] 1. A ball end mill in which a rounded cutting edge that performs spherical cutting consists of one long blade 1 passing through the rotation center axis 6 and at least one short blade 2, wherein the long blade 1 and the short blade 2 are connected to each other. The notch 3 that separates the blade 2 from the
The respective second surfaces 4 and 5 of the long blade 1 and short blade 2
By forming a chamfer with a smoothly continuous curved surface, these ridgelines transitioning from the cutting edge ridgelines of the long blade 1 and the short blade 2 to the ridgeline portion of the notch 3 form a smoothly continuous curve. A ball end mill characterized in that a radial rake angle (θ) of the long blade 1 and the short blade 2 with respect to the center of the spherical surface is set to −15° or more and 0° or less.