JP6941047B2 - Manufacturing method for rotary tools and cuttings - Google Patents

Description

This aspect relates to a rotary tool used in cutting.

As a rotary tool used when cutting a work material such as metal, for example, the drills described in Patent Documents 1 and 2 are known. The drill described in Patent Document 1 has a cutting edge, a thinning surface located along the cutting edge, and a chip discharge groove. The cutting edge in Patent Document 1 has one linear shape. The drill described in Patent Document 2 has a central cutting edge located in a thinning portion, a main cutting edge, and a chip groove extending from the main cutting edge. The central cutting edge in Patent Document 2 has a convex curved shape when viewed from the front.

Japanese Unexamined Patent Publication No. 2012-030306 Special Table 2016-529124

In the drill described in Patent Document 1, the cutting edge has one linear shape. Therefore, when the drill comes into contact with the work material, the cutting resistance may rise sharply, causing large chatter vibration. Further, the drill described in Patent Document 2 has a convex curved shape when the central cutting edge is viewed from the front. A large load may be applied to the central cutting edge located on the center side as compared with the main cutting edge, but the durability of the central cutting edge may decrease when such a large load is applied.

A rotary tool based on one embodiment has a rotating shaft and includes a rod-shaped main body extending from the first end to the second end, and the main body is located on the side of the first end and is viewed from the front. A chisel edge extending from the rotation axis toward the outer periphery of the main body, a linear inner thinning blade extending from the chisel edge, and a linear outer thinning blade extending at a different angle from the inner thinning blade. A cutting edge having a main cutting edge extending from the outer thinning blade, a flat first inner thinning surface located along the inner thinning blade, and a flat first outer surface located along the outer thinning blade. A concave curved second inner thinning surface adjacent to the thinning surface in front of the first inner thinning surface in the rotation direction of the rotation axis, and a front in the rotation direction with respect to the second inner thinning surface. With respect to the flat third inner thinning surface adjacent to the first outer thinning surface, the concave curved second outer thinning surface adjacent to the first outer thinning surface in front of the rotation direction, and the second outer thinning surface. It is provided with a flat third outer thinning surface adjacent to each other in front of the rotation direction, and a spiral groove extending from the main cutting edge toward the second end side of the main body.

According to the rotary tool of the above aspect, the durability of the cutting edge is high and the chatter vibration is small.

It is a perspective view which shows the rotary tool of embodiment. It is an enlarged view in the region A1 shown in FIG. It is a front view of the rotary tool shown in FIG. FIG. 5 is a side view of the cutting insert shown in FIG. 3 as viewed from the B1 direction. FIG. 5 is a side view of the cutting insert shown in FIG. 3 as viewed from the B2 direction. It is an enlarged view in the region A2 shown in FIG. It is sectional drawing of the cross section of C1-C1 shown in FIG. It is sectional drawing of the C2-C2 cross section shown in FIG. It is a schematic diagram which shows one process of the manufacturing method of the cut-worked article of embodiment. It is a schematic diagram which shows one process of the manufacturing method of the cut-worked article of embodiment. It is a schematic diagram which shows one process of the manufacturing method of the cut-worked article of embodiment.

Hereinafter, the rotary tool 1 of the embodiment will be described in detail with reference to the drawings. However, for convenience of explanation, each figure referred to below is a simplified representation of only the main members necessary for explaining the embodiment. Therefore, the rotary tool 1 disclosed below may include any component not shown in each of the referenced figures. Further, the dimensions of the members in each drawing do not faithfully represent the actual dimensions of the constituent members, the dimensional ratio of each member, and the like.

<Drill>
An example of the rotary tool 1 of the embodiment is a drill 1. Examples of the rotary tool 1 include an end mill and the like in addition to the drill 1.

The drill 1 of the present disclosure has a rotation axis X, and includes a rod-shaped body 3 extending from a first end 3a to a second end 3b. The drill 1 shown in FIG. 1 extends in a direction along the rotation axis X. When cutting a work material for manufacturing a work piece, the main body 3 can rotate about a rotation axis X. Hereinafter, the first end 3a will be referred to as the front end 3a and the second end 3b will be referred to as the rear end 3b. Further, the side closer to the rotation axis X is the central side, and the side far from the rotation axis X is the outer peripheral side. Further, the direction from the rear end 3b of the main body 3 to the tip 3a is the front end direction, and the direction from the front end 3a to the rear end 3b of the main body 3 is the rear end direction.

The main body 3 of the example shown in FIG. 1 is composed of a grip portion 5 (shank portion) and a cutting portion 7 (cutting portion). The grip portion 5 is a portion gripped by a rotating spindle or the like of a machine tool (not shown), and is a portion designed according to the shape of the spindle or the like in the machine tool. The cutting portion 7 is located on the side of the tip 3a with respect to the grip portion 5. The cutting portion 7 is a portion including a portion that comes into contact with the work material, and is a portion that plays a main role in the cutting process of the work material. The arrow Y in FIG. 1 and the like indicates the rotation direction of the main body 3 about the rotation axis X.

The cutting portion 7 may be composed of one member, or may be composed of a plurality of members. As in the example shown in FIG. 1, the drill 1 in which the cutting portion 7 is composed of one member is generally called a solid drill. Further, the cutting portion 7 may be composed of a first member located on the side of the tip 3a and a second member located on the side of the rear end 3b. The drill 1 is generally called a throw-away drill when the cutting portion 7 is composed of a plurality of members and the first member on the side of the tip 3a is replaceable. At this time, the first member is generally called a throw-away tip.

The main body 3 of the present disclosure includes a cutting edge 9 located on the side of the tip 3a. The cutting edge 9 can be used as a portion for cutting the work material. The cutting edge 9 in the example shown in FIG. 3 has a chisel edge 11, an inner thinning edge 13, an outer thinning edge 15, and a main cutting edge 17. ing. In the following description, when both the inner thinning blade 13 and the outer thinning blade 15 are referred to, they may be simply referred to as a thinning blade.

The chisel edge 11 in the example shown in FIG. 3 extends from the rotation axis X toward the outer circumference of the main body 3 when viewed from the front. In the chisel edge 11 of the example shown in FIG. 3, the rake angle has a negative value, and it is possible to function to crush the work material rather than to cut the work material. The chisel edge 11 of an example shown in FIG. 3 has a linear shape when frontal. The chisel edge 11 in the front view is not limited to the above configuration, and may have a curved shape.

The inner thinning blade 13 in the example shown in FIG. 3 has a linear shape and extends from the chisel edge 11 toward the outer periphery of the main body 3. The rake angle of the inner thinning blade 13 may be 0 °, a positive value, or a negative value. The rake angle of the inner thinning blade 13 of the example shown in FIG. 2 is approximately 0 °.

When viewed from the front, the inner thinning blade 13 may intersect the chisel edge 11 at an obtuse angle. When the inner thinning blade 13 intersects the chisel edge 11 at an obtuse angle, it is easy to avoid applying a large cutting load in the vicinity of the boundary between the chisel edge 11 and the inner thinning blade 13. Therefore, the durability of the cutting edge 9 is high.

The inner thinning blade 13 of the example shown in FIG. 3 is directly connected to the chisel edge 11, but is not limited to such a configuration. A curved edge shorter than these blades and connecting these blades may be located between the chisel edge 11 and the inner thinning blade 13.

The outer thinning blade 15 in the example shown in FIG. 3 has a linear shape and extends from the inner thinning blade 13 toward the outer periphery of the main body 3 at different angles. The rake angle of the outer thinning blade 15 may be 0 °, a positive value, or a negative value. The rake angle of the outer thinning blade 15 in the example shown in FIG. 2 is approximately 0 °.

When viewed from the front, the outer thinning blade 15 may intersect the inner thinning blade 13 at an obtuse angle. When the outer thinning blade 15 intersects the inner thinning blade 13 at an obtuse angle, it is easy to avoid applying a large cutting load near the boundary between the inner thinning blade 13 and the outer thinning blade 15. Therefore, the durability of the cutting edge 9 is high.

The outer thinning blade 15 of the example shown in FIG. 3 is directly connected to the inner thinning blade 13, but is not limited to such a configuration. A curved blade shorter than these blades and connecting these blades may be located between the inner thinning blade 13 and the outer thinning blade 15.

The main cutting blade 17 in the example shown in FIG. 3 extends from the outer thinning blade 15 toward the outer circumference of the main body 3. The main cutting edge 17 of the example shown in FIG. 3 has a positive rake angle and can cut a work material. The main cutting edge 17 may have a linear shape or a curved shape when viewed from the front. The main cutting edge 17 in the example shown in FIG. 3 has a concave curved shape that is recessed with respect to the rotation direction Y when viewed from the front.

When viewed from the front, the main cutting blade 17 may intersect the outer thinning blade 15 at an obtuse angle. When the main cutting blade 17 intersects the outer thinning blade 15 at an obtuse angle, it is easy to avoid applying a large cutting load near the boundary between the outer thinning blade 15 and the main cutting blade 17. Therefore, the durability of the cutting edge 9 is high.

The main cutting blade 17 of the example shown in FIG. 3 is directly connected to the outer thinning blade 15, but is not limited to such a configuration. A curved blade shorter than these blades and connecting these blades may be located between the outer thinning blade 15 and the main cutting blade 17.

The drill 1 may include one chisel edge 11, one inner thinning blade 13, one outer thinning blade 15 and one main cutting blade 17, and may also include a plurality of chisel edges 11, a plurality of inner thinning blades 13, and a plurality of inner thinning blades 13. A plurality of outer thinning blades 15 and a plurality of main cutting blades 17 may be provided. The drill 1 in the example shown in FIG. 3 includes two chisel edges 11, two inner thinning blades 13, two outer thinning blades 15, and two main cutting blades 17.

The main body 3 of the present disclosure includes a first inner thinning surface 19 and a first outer thinning surface 21. The first inner thinning surface 19 is located along the inner thinning blade 13. The first inner thinning surface 19 is a surface on which chips generated by the inner thinning blade 13 flow. The first outer thinning surface 21 is located along the outer thinning blade 15. The first outer thinning surface 21 is a surface on which chips generated by the outer thinning blade 15 flow. The first inner thinning surface 19 and the first outer thinning surface 21 may be formed for the main purpose of reducing the cutting resistance during cutting, respectively.

Further, the first inner thinning surface 19 and the first outer thinning surface 21 in the present disclosure are flat, respectively. In the example shown in FIG. 2, since the rake angles of the inner thinning blade 13 and the outer thinning blade 15 are 0 °, the first inner thinning surface 19 and the first outer thinning surface 21 are respectively relative to the rotation axis X. Is parallel.

Here, the fact that the first inner thinning surface 19 is parallel to the rotation axis X means that the virtual plane is orthogonal to the virtual plane including the flat first inner thinning surface 19 and includes the rotation axis X. And the rotation axes X are parallel. The fact that the first outer thinning surface 21 is parallel to the rotation axis X means that the virtual plane and the rotation axis X are orthogonal to the virtual plane including the flat first outer thinning surface 21 and include the rotation axis X. Means that are parallel. However, the above-mentioned parallelism is not limited to parallelism in a strict sense, and is intended to include a slight inclination of about 5 °.

The main body 3 of the present disclosure includes a spiral groove 23. The groove 23 extends from the main cutting edge 17 toward the rear end 3b side of the main body 3. At this time, the groove 23 may extend toward the rear end 3b side, and may not necessarily reach the rear end 3b of the main body 3. The groove 23 can be used to discharge the chips generated by the cutting edge 9 to the outside. The groove 23 of the example shown in FIG. 1 extends spirally around the rotation axis X. Since the drill 1 of the example shown in FIG. 1 includes two main cutting blades 17, it includes not only one but two grooves 23.

The helix angle of the spirally extending groove 23 may be constant from the side of the tip 3a to the side of the rear end 3b, or may change in the middle. The helix angle means the angle formed by the leading edge and the virtual straight line parallel to the rotation axis X. The leading edge is indicated by a line of intersection formed by the groove 23 and a margin located on the rear side in the rotation direction Y with respect to the groove 23. The helix angle may be set to, for example, about 3 to 45 °.

The main body 3 of the present disclosure has an inner thinning blade 13 and an outer thinning blade 15 as described above. Therefore, when the drill 1 comes into contact with the work material, large chatter vibration is unlikely to occur. Further, since the inner thinning blade 13 and the outer thinning blade 15 each have a linear shape, the durability of the thinning blade as a whole is high. That is, the durability of the cutting edge 9 in the drill 1 of the present disclosure is high.

As shown in FIG. 1, the drill 1 has a shape obtained by removing a groove 23 and a portion corresponding to clearance from a columnar body extending along the rotation axis X, for example. Therefore, in the cross section orthogonal to the rotation axis X, except for the groove 23 and the clearance on the outer circumference of the cutting portion 7, the portion corresponding to the margin or the like has an arc shape located on the same circle. The diameter of this same circle corresponds to the outer diameter of the drill 1.

The drill 1 is not limited to a specific size, but may be set to, for example, an outer diameter of 6 mm to 42.5 mm. Further, the drill 1 may be set to L = 3D to 12D, for example, when the length from the front end 3a to the rear end 3b is L and the outer diameter is D.

Further, the depth of the groove 23 may be set to about 10 to 40% with respect to the above outer diameter. Here, the depth of the groove 23 means a value obtained by subtracting the distance between the bottom of the groove 23 and the rotation axis X from the radius of the main body 3 in the cross section orthogonal to the rotation axis X. The bottom means the portion of the groove 23 closest to the rotation axis X.

Therefore, the diameter of the core thickness indicated by the diameter of the inscribed circle in the cross section orthogonal to the rotation axis X in the main body 3 may be set to about 20 to 80% with respect to the outer diameter. Specifically, for example, when the outer diameter is 20 mm, the depth of the groove 23 can be set to about 2 to 8 mm.

The material of the main body 3 is a cemented carbide containing WC (titanium carbide) and Co (cobalt) as a binder, and an additive such as TiC (titanium carbide) or TaC (tantal carbide) is added to the cemented carbide. Examples include alloys containing, and metals such as stainless steel and titanium.

As described above, the cutting blade 9 in the present disclosure has an inner thinning blade 13 and an outer thinning blade 15. The lengths of the inner thinning blade 13 and the outer thinning blade 15 when viewed from the front are not particularly limited. For example, as shown in FIG. 3, the outer thinning blade 15 may be longer than the inner thinning blade 13.

The inner thinning blade 13 is located closer to the rotation axis X than the outer thinning blade 15. Therefore, the cutting speed of the inner thinning blade 13 is slower than the cutting speed of the outer thinning blade 15 when cutting the work material. When the entire inner thinning blade 13 and outer thinning blade 15 come into contact with the work material, chatter vibration is suppressed when the length of the outer thinning blade 15 having a relatively high cutting speed is relatively long. .. Further, when the inner thinning blade 13 is shorter than the outer thinning blade 15, the increase in cutting resistance when the cutting blade starts to bite into the work material is likely to be suppressed.

When viewed from the side, the inner thinning blade 13 and the outer thinning blade 15 may be orthogonal to the rotation axis X or may be inclined, respectively. In the example shown in FIG. 6, the inner thinning blade 13 and the outer thinning blade 15 extend in directions orthogonal to the rotation axis X, respectively. When the inner thinning blade 13 and the outer thinning blade 15 extend in directions orthogonal to the rotation axis X, it is easy to flatten the bottom surface of the machined hole when drilling the work material.

On the other hand, when viewed from the side, when the inner thinning blade 13 and the outer thinning blade 15 extend in directions orthogonal to the rotation axis X, the thinning blade is formed when the drill 1 comes into contact with the work material. Since the entire surface of the blade easily comes into contact with the work material, chatter vibration tends to increase. However, in the example drill 1 shown in FIG. 3, the thinning blade is composed of the inner thinning blade 13 and the outer thinning blade 15. Therefore, it is easy to form the bottom surface of a flat machined hole while suppressing chatter vibration.

The above-mentioned "direction orthogonal to the rotation axis X" does not mean that the direction is exactly orthogonal to the rotation axis X, and a deviation of about 5 ° is allowed. That is, when viewed from the side, the angle formed by the inner thinning blade 13 and the outer thinning blade 15 and the rotation axis X may be about 85 to 95 °.

Further, when viewed from the side, when the inner thinning blade 13 and the outer thinning blade 15 are located on one virtual straight line S1, it is easier to flatten the bottom surface of the machined hole.

The main body 3 of the example shown in FIGS. 3 and 6 further includes a second inner thinning surface 25, a third inner thinning surface 27, a second outer thinning surface 29, and a third outer thinning surface 31. The second inner thinning surface 25 is adjacent to the first inner thinning surface 19 in front of the rotation direction Y, and has a concave curved surface shape. The third inner thinning surface 27 is adjacent to the second inner thinning surface 25 in front of the rotation direction Y and is flat. The second outer thinning surface 29 is adjacent to the first outer thinning surface 21 in front of the rotation direction Y, and has a concave curved surface shape. The third outer thinning surface 31 is adjacent to the second outer thinning surface 29 in front of the rotation direction Y and is flat.

In the example shown in FIGS. 3 and 6, the region composed of the first inner thinning surface 19, the second inner thinning surface 25, and the third inner thinning surface 27 may be paraphrased as the inner thinning portion. Further, the region composed of the first outer thinning surface 21, the second outer thinning surface 29, and the third outer thinning surface 31 may be rephrased as the outer thinning portion.

When the main body 3 has the above-mentioned inner thinning portion, the chips generated by the inner thinning blade 13 are highly discharged. Further, when the main body 3 has the above-mentioned outer thinning portion, the chips generated by the outer thinning blade 15 are highly discharged.

In particular, when the first inclination angle θ11 with respect to the rotation axis X of the third outer thinning surface 31 is smaller than the second inclination angle θ12 with respect to the rotation axis X of the third inner thinning surface 27, the chip evacuation property is further high. .. While the chips generated by the inner thinning blade 13 flow into the inner thinning portion, the chips generated by the outer thinning blade 15 and the chips that have passed through the inner thinning portion flow into the outer thinning portion. When the first inclination angle θ11 is smaller than the second inclination angle θ12, the space of the outer thinning portion is wider than that when the first inclination angle θ11 is the same as the second inclination angle θ12. Therefore, the chip discharge property is even higher.

The first inclination angle θ11 can be evaluated by the inclination angle of the virtual plane with respect to the rotation axis X in the cross section including the rotation axis X while being orthogonal to the virtual plane including the flat third outer thinning surface 31. Further, the second inclination angle θ12 can be evaluated by the inclination angle of the virtual plane with respect to the rotation axis X in the cross section including the rotation axis X while being orthogonal to the virtual plane including the flat third inner thinning surface 27.

Further, as in the example shown in FIGS. 7 and 8, the first angle θ21 where the first inner thinning surface 19 and the third inner thinning surface 27 intersect is the first outer thinning surface 21 and the third outer thinning surface 3.
Even when it is larger than the second angle θ22 where 1 intersects, the chip evacuation property is high. When the first angle θ21 is larger than the second angle θ22, the chips generated by the thinning blade are likely to be curled with a small diameter. As a result, the chips generated by the thinning blade can easily flow through the groove 23, so that the chips can be discharged easily.

The first angle θ21 can be evaluated by the angle formed by the first inner thinning surface 19 and the third inner thinning surface 27 in the cross section orthogonal to each of the first inner thinning surface 19 and the third inner thinning surface 27. Further, the second angle θ22 can be evaluated by the angle formed by the first outer thinning surface 21 and the third outer thinning surface 31 in the cross section orthogonal to each of the first outer thinning surface 21 and the third outer thinning surface 31.

In the example shown in FIG. 6, the ridge line S2 at which the first inner thinning surface 19 and the first outer thinning surface 21 intersect has a linear shape. Further, the ridge line S3 at which the second inner thinning surface 25 and the second outer thinning surface 29 intersect has a convex shape protruding toward the rear end 3b. Further, the ridge line S4 where the third inner thinning surface 27 and the third outer thinning surface 31 intersect has a linear shape. When the boundary between the inner thinning portion and the outer thinning portion has the above configuration, the chips generated by the inner thinning blade 13 are less likely to be clogged in the vicinity of the boundary between the inner thinning portion and the outer thinning portion, and pass through the inner thinning portion to the outside. Easy to flow to the thinning part. Therefore, the chip discharge property is high.

Further, in the example shown in FIG. 6, the end portion 27a on the rear end 3b side of the third inner thinning surface 27 is located closer to the rear end 3b than the third outer thinning surface 31. Since the inner thinning blade 13 is located closer to the center than the outer thinning blade 15, the cutting speed of the inner thinning blade 13 is slower than the cutting speed of the outer thinning blade 15. Therefore, the traveling direction of the chips generated by the inner thinning blade 13 tends to be more unstable than the traveling direction of the chips generated by the outer thinning blade 15. However, when the end 27a on the third inner thinning surface 27 is located closer to the rear end 3b than the third outer thinning surface 31, the traveling direction of the chips generated by the inner thinning blade 13 is the third inner. It is easy to control on the thinning surface 27. Therefore, the chip discharge property is high.

<Manufacturing method of machined product>
Next, the method of manufacturing the machined product of the embodiment will be described in detail with reference to the case where the drill 1 according to the above-mentioned example of the embodiment is used as an example. Hereinafter, description will be made with reference to FIGS. 9 to 11. Note that in FIGS. 9 to 11, the machine tool that grips the grip portion is omitted.

The method for manufacturing a machined product according to the embodiment includes the following steps (1) to (4).

(1) A step of arranging the drill 1 above the prepared work material 101 (see FIG. 9).

(2) A step of rotating the drill 1 around the rotation axis X in the direction of the arrow Y and bringing the drill 1 closer to the work material 101 in the Z1 direction (see FIGS. 9 and 10).

This step can be performed, for example, by fixing the work material 101 on the table of the machine tool to which the drill 1 is attached and bringing the drill 1 closer in a rotated state. In this step, the work material 101 and the drill 1 may be relatively close to each other, and the work material 101 may be brought close to the drill 1.

(3) By bringing the drill 1 closer to the work material 101, the cutting edge of the rotating drill 1 is brought into contact with a desired position on the surface of the work material 101, and the machined hole 103 is made into the work material 101. Step of forming (through hole) (see FIG. 10).

In this step, the entire cutting portion of the drill 1 may penetrate the work material 101, and a part of the cutting portion of the drill 1 on the rear end side does not penetrate the work material 101. May be set to. When a part of the cutting portion of the drill 1 on the rear end side is set so as not to penetrate the work material 101, a good finished surface can be obtained. Specifically, by making a part of the above-mentioned regions function as a region for chip discharge, it is possible to achieve excellent chip discharge through the region.

(4) A step of separating the drill 1 from the work material 101 in the Z2 direction (see FIG. 11).

In this step as well, as in the step (2) described above, the work material 101 and the drill 1 may be relatively separated from each other. For example, the work material 101 may be separated from the drill 1.

By going through the above steps, a machined product having a machined hole 103 can be obtained.

When the work material 101 is cut a plurality of times as shown above, for example, when a plurality of machined holes 103 are formed in one work material 101, the drill 1 is rotated. The process of bringing the cutting edge of the drill 1 into contact with different parts of the work material 101 may be repeated while maintaining the state.

Although the cutting tool of the embodiment has been illustrated above, it goes without saying that the cutting tool of the present invention is not limited to the above-described embodiment and can be arbitrary as long as it does not deviate from the gist of the present invention. For example, the cutting tool according to the example of the embodiment is a drill, but there is no problem even if it is an end mill to which the gist of the present invention is applied.

1 ... Rotary tool (drill)
3 ... Main body 3a ... 1st end (tip)
3b ... 2nd end (rear end)
5 ... Gripping part 7 ... Cutting part 9 ... Cutting blade 11 ... Chisel edge 13 ... Inner thinning blade 15 ... Outer thinning blade 17 ... Main cutting blade 19 ... 1st Inner thinning surface 21 ... 1st outer thinning surface 23 ... Groove 25 ... 2nd inner thinning surface 27 ... 3rd inner thinning surface 29 ... 2nd outer thinning surface 31 ... 3rd Outer thinning surface 101 ・ ・ ・ Work material 103 ・ ・ ・ Machined hole

Claims (10)

It has a rotating shaft and has a rod-shaped body that extends from the first end to the second end.
The main body is
When it is located on the side of the first end and is viewed from the front,
A chisel edge extending from the rotation axis toward the outer circumference of the main body,
A linear inner thinning blade extending from the chisel edge,
A linear outer thinning blade extending at different angles from the inner thinning blade,
The main cutting blade extending from the outer thinning blade and
With a cutting edge,
A flat first inner thinning surface located along the inner thinning blade,
A flat first outer thinning surface located along the outer thinning blade,
A concave curved second inner thinning surface adjacent to the first inner thinning surface in front of the rotation axis in the rotation direction.
A flat third inner thinning surface adjacent to the second inner thinning surface in front of the rotation direction.
A concave curved second outer thinning surface adjacent to the first outer thinning surface in the front in the rotational direction.
A flat third outer thinning surface adjacent to the second outer thinning surface in front of the rotation direction,
A rotary tool comprising a spiral groove extending from the main cutting edge toward the second end side of the main body. The rotary tool according to claim 1, wherein the inner thinning blade and the outer thinning blade intersect at an obtuse angle when viewed from the front. The rotary tool according to claim 1 or 2, wherein the outer thinning blade is longer than the inner thinning blade when viewed from the front. The rotation according to any one of claims 1 to 3, wherein the inner thinning blade and the outer thinning blade each extend in a direction orthogonal to the rotation axis when viewed from the side. tool. The rotary tool according to claim 4, wherein the inner thinning blade and the outer thinning blade are located on one virtual straight line when viewed from the side. One of claims 1 to 5 , wherein the first inclination angle of the third outer thinning surface with respect to the rotation axis is smaller than the second inclination angle of the third inner thinning surface with respect to the rotation axis. The rotary tool described in. Claim 1, wherein the first inner thinned face and first angle of intersection of the third in the thinned face is characterized by greater than a second angle of intersection of said first outer thinned face and the third outer thinned face The rotary tool according to any one of 6. The ridgeline where the first inner thinning surface and the first outer thinning surface intersect has a linear shape.
When viewed from the side, the ridgeline where the second inner thinning surface and the second outer thinning surface intersect has a convex shape protruding toward the second end.
The rotary tool according to any one of claims 1 to 7 , wherein the ridge line at which the third inner thinning surface and the third outer thinning surface intersect has a linear shape. Any of claims 1 to 8 , wherein the end of the third inner thinning surface on the side of the second end is located closer to the second end than the third outer thinning surface. The rotary tool described in one. The step of rotating the rotary tool according to any one of claims 1 to 9,
The process of bringing the rotating rotating tool into contact with the work material, and
A method for manufacturing a work piece, which comprises a step of separating the rotary tool from the work material.

Images