JP5849817B2 - Square end mill - Google Patents

Description

  The present invention relates to a square end mill in which an outer peripheral blade formed on the outer periphery of a tip end portion of an end mill body and a bottom blade formed on the distal end intersect each other at right angles or slightly at an acute angle.

  Such a square end mill has a chip discharge groove that is twisted with respect to the axis of the end mill body so as to open toward the rear end side of the end mill body and toward the rear end side as it goes toward the rear end side. The outer peripheral blade is formed on the outer peripheral side ridge portion of the wall surface facing the front side in the end mill rotation direction of the chip discharge groove, and the inner peripheral portion of the chip discharge groove is formed at the tip of the chip discharge groove. A groove-shaped gash is formed so as to be cut out, and a direction perpendicular to the outer peripheral edge or orthogonal to the intersecting ridge line part of the wall surface facing the front side in the end mill rotation direction of the gash and the end flank of the end mill body A bottom blade extending in a direction slightly intersecting with an acute angle is formed.

  By the way, in such a square end mill, the gasche extends to the middle of the wall surface facing the front side in the end mill rotation direction of the chip discharge groove without the wall surface facing the front side in the end mill rotation direction reaching the outer peripheral blade. In addition, it is known that the outer peripheral side from the wall surface of the gasche is formed with a bottom blade at the intersecting ridge line portion between the wall surface facing the front side in the end mill rotation direction of the chip discharge groove and the tip flank surface.

  However, in such a case, on the outer peripheral side of the bottom blade, the axial rake angle is equal to the twist angle with respect to the axis of the chip discharge groove and the outer peripheral blade. Therefore, when this twist angle is a strong twist of 45 ° or more, for example, The cutting edge strength on the outer peripheral side of the metal is lost, and defects are likely to occur. Therefore, in Patent Documents 1 and 2, the wall surface facing the front side in the rotation direction of the end of the gash is extended to the outer peripheral blade and intersected with the outer peripheral flank. Proposals have been made to reduce the rake angle.

JP 2004-283965 A JP 2008-200187 A

  In these square end mills described in Patent Documents 1 and 2, the clearance angle is extremely small on the rear side in the end mill rotation direction of the outer peripheral blade, or the width forms a cylindrical surface shape having an outer diameter equal to that of the outer peripheral blade with a clearance angle of 0 °. A narrow margin is provided, and an outer peripheral flank face that recedes toward the inner peripheral side with respect to the rotational trajectory around the axis of the outer peripheral blade is formed at a predetermined clearance angle on the rear side in the end mill rotational direction. Of these, in the square end mill described in Patent Document 2, the axial width of the wall surface facing the front side in the end mill rotation direction of the gash at the tip of the outer peripheral blade is made wider than the axial width of the margin. .

  However, in such a square end mill described in Patent Document 2, the wall surface facing the front side in the rotational direction of the end of the gasche is crossed over the outer peripheral flank that recedes from the margin toward the inner peripheral side, and the crossed ridgeline Since the tip of the outer peripheral blade is formed in the part, the outer peripheral blade inclines toward the inner peripheral side of the end mill body toward the front end side at the most distal portion of the outer peripheral blade that intersects the outer peripheral flank. The outer diameter of the blade is reduced and the processing accuracy is impaired. This is a square end mill that has an outer peripheral flank that is retracted directly to the inner peripheral side on the rear side in the end mill rotation direction of the outer peripheral blade without providing a margin. The same applies when crossing.

  On the other hand, in the square end mill described in Patent Document 1, a margin is provided on the rear side in the end mill rotation direction over the entire length of the outer peripheral blade, including the portion where the wall surface facing the front side in the end mill rotation direction of the gasche intersects the outer peripheral clearance surface. Therefore, the outer diameter can be made constant even at the tip of the outer peripheral blade. However, since the margin is a cylindrical surface having an outer diameter that is as small as 0 ° or equal to the outer peripheral blade as described above, such a margin is provided over the entire length of the outer peripheral blade. If this is done, the margin will slidably contact the work surface of the work material, leading to an increase in cutting resistance.

  In addition, as in the square end mills described in Patent Documents 1 and 2, the wall surface facing the front side in the rotation direction of the end of the gasche is extended to the outer peripheral flank, and the outer peripheral blade at the tip of the outer peripheral blade. A corner portion in which the torsion angle (axial rake angle) of the steel plate changes abruptly is formed, and there is a risk that chipping or the like may occur due to concentration of a load on the corner portion during cutting.

  The present invention has been made under such a background. Even if the twist discharge angle of the chip discharge groove and the outer peripheral blade is large, the bottom blade and the outer peripheral blade are not damaged or chipped, and the entire length of the outer peripheral blade is increased. Accordingly, it is an object of the present invention to provide a square end mill that can maintain the machining accuracy with a constant outer diameter and that does not cause an increase in cutting resistance.

In order to solve the above-mentioned problems and achieve such an object, the present invention provides an outer periphery of the tip end of the end mill body that is rotated around the axis, and opens toward the rear end side of the end mill body. A chip discharge groove extending toward the rear side in the end mill rotation direction is formed, and a wall surface facing the front side in the end mill rotation direction of the chip discharge groove has a concave curve shape recessed toward the rear side in the end mill rotation direction in a cross section orthogonal to the axis. None, at the intersection ridge line portion between the wall surface and the outer peripheral flank of the end mill body, an outer peripheral blade having the concave wall surface as a rake face is formed, and on the outer peripheral side of the tip end portion of the chip discharge groove. is not the rake face having the above-described cross-sectional concave-curved is left, the intersecting edge line region with at least the outer peripheral portion and the tip flank of the end mill body of the wall, the end mill body In the outer peripheral side are end cutting edge which intersects at an angle the tip portion of the peripheral cutting edge is formed as a common rake face the rake face of the peripheral cutting edge, the distal end portion of the outer peripheral cutting edge, relative to the axis of the outer circumferential edge A torsional angle gradually decreasing portion is formed which gradually decreases as the torsional angle moves toward the tip side, and the outer peripheral blade includes the torsional angle gradually decreasing portion and a cylindrical surface having a constant outer diameter around the axis including the torsional angle gradually decreasing portion. And the outer peripheral flank is formed so as to gradually recede toward the inner peripheral side with respect to the rotation trajectory of the outer peripheral blade around the axis from the outer peripheral blade toward the rear side in the end mill rotation direction. It is characterized by.

  In the square end mill configured as described above, a torsion angle gradually decreasing portion is formed at the tip end portion of the outer peripheral blade that gradually decreases as the torsion angle with respect to the axial line moves toward the tip end side. The blade extends toward the front side in the end mill rotation direction toward the tip side while drawing a convex curve. Therefore, even if the twist discharge angle of the chip discharge groove and the outer peripheral blade on the rear end side of the end mill main body is a strong twist, while preventing the outer blade from changing abruptly due to a sudden change in the twist angle of the outer peripheral blade, The blade angle of the outer peripheral portion of the bottom blade intersecting the tip portion can be increased, and the outer peripheral blade and the bottom blade can be prevented from being broken or chipped.

  On the other hand, the outer peripheral blade extends from the front end portion to the rear end side including the torsion angle gradually decreasing portion, and the rotation trajectory around the axis is a cylindrical surface with a constant outer diameter centered on the axis. The flank face is formed so as to gradually recede from the outer peripheral blade including the gradually decreasing portion of the torsion angle toward the rear side in the end mill rotation direction toward the inner peripheral side with respect to the rotation trajectory around the axis of the outer peripheral blade. That is, since there is no margin, it is possible to prevent the outer diameter of the outer peripheral blade from becoming small even at the portion where the torsional angle gradually decreases while preventing an increase in cutting resistance due to the sliding contact of the margin, and high machining accuracy can be obtained.

  Here, the tip end portion of the outer peripheral blade may be the aforementioned torsion angle gradually decreasing portion to the tip of the outer peripheral blade intersecting with the bottom blade, and the torsion angle may be gradually decreased to the tip. A constant torsion angle portion in which the torsion angle is constant is formed on the tip end side of the portion, and the outer peripheral blade includes the constant torsion angle portion and the rotation trajectory around the axis includes a constant outer diameter centered on the axis. By making the cylindrical surface shape of this, it is possible to widen the range in which the blade angle of the bottom blade is increased, and more reliably prevent the occurrence of defects or the like. In addition, it is desirable that the twist angle at the tip of the outer peripheral blade gradually decreasing by the twist angle gradually decreasing portion is in the range of 0 ° to 20 °. If the negative angle is smaller than 0 °, the cutting resistance may be increased. On the other hand, when it is larger than 20 °, it may be difficult to reliably prevent the outer peripheral portion of the bottom blade connected to the tip portion of the outer peripheral blade from being damaged.

  As described above, according to the present invention, it is possible to prevent corners from being formed at the tip of the outer peripheral blade and to ensure a large blade angle at the outer peripheral portion of the bottom blade, and to chip the outer peripheral blade and the bottom blade. It is possible to maintain machining accuracy by preventing an increase in cutting resistance and preventing the rotation trajectory of the outer peripheral blade from becoming smaller at the tip portion while preventing the occurrence of defects.

It is a perspective view which shows one Embodiment of this invention. It is a side view of embodiment shown in FIG. It is an enlarged front view of embodiment shown in FIG. It is YY sectional drawing in FIG. It is ZZ sectional drawing in FIG. It is an enlarged side view which shows the front-end | tip part of the outer periphery blade of embodiment shown in FIG.

  1 to 6 show an embodiment of the present invention. In the present embodiment, the end mill body 1 is integrally formed of a hard material such as cemented carbide in a substantially cylindrical shaft shape with the axis O as the center, and a rear end portion (upper right side portion in FIG. 1; FIG. 2). The upper part) is a cylindrical shank part 2 and the tip part (the lower left part in FIG. 1, the lower part in FIG. 2) is the cutting edge part 3. In such an end mill, the shank portion 2 is gripped by the main spindle of the machine tool, and is rotated in the end mill rotation direction T around the axis O, and is usually fed in a direction crossing the axis O, and is cut by the cutting edge portion 3. Cutting material.

  On the outer periphery of the cutting edge portion 3 at the tip end portion of the end mill body 1, there are four pieces of chip discharge grooves 4 that are twisted toward the rear side in the end mill rotation direction T around the axis O as it goes from the tip end of the cutting blade portion 3 toward the rear end side. They are formed at intervals (equal intervals in this embodiment) in the circumferential direction. The wall surfaces of the chip discharge grooves 4 facing the end mill rotation direction T have a concave curve that is recessed toward the rear side in the end mill rotation direction T as shown in FIG.

  Then, at the intersecting ridge line portion between the wall surface and the outer peripheral flank 5 of the end mill body 1, an axis line from the front end to the rear end side of the cutting edge portion 3, similar to each chip discharge groove 4, with the wall surface as the rake face 6. The outer peripheral blade 7 is twisted to the rear side in the end mill rotation direction T around O, and the outer peripheral blade 7 whose rotation locus around the axis O forms a cylindrical surface with a constant outer diameter around the axis O is also spaced in the circumferential direction. They are formed at equal intervals. The torsion angle θ of the outer peripheral blade 7 is, for example, 45 °, excluding the tip portion described later.

  Further, a concave groove-like gash 8 is formed at the tip of each chip discharge groove 4 so as to cut out the inner peripheral part thereof toward the inner peripheral side of the end mill body 1. Here, as shown in FIG. 2, the gash 8 in the present embodiment has an end mill main body in which the wall surface facing the front side in the end mill rotation direction T and the wall surface facing the rear direction in the end mill rotation direction T face the rear side in the end mill rotation direction T. 1 The bottom part on the inner peripheral side of the rear end has a substantially V-shaped cross section connected through a concave curved surface, and at least the wall surface facing the front side in the end mill rotation direction T is flat.

  However, the gash 8 is formed only on the inner peripheral portion of the chip discharge groove 4, and the rake face 6 of the outer peripheral blade 7 having a concave cross-sectional shape as described above is formed on the outer peripheral side of the tip end portion of the chip discharge groove 4. It is left. And the wall surface which faces the end mill rotation direction T side of these gashes 8 and the rake face 6 of the outer peripheral blade 7 and the wall surface which faces the front side of the end mill rotation direction T of the chip discharge groove 4 and the tip flank of the tip of the cutting blade portion 3 9 is a rake face 10 on the inner peripheral side facing the front side of the end mill rotation direction T of the gash 8 and the rake face 6 of the outer peripheral edge 7 is a common rake face 4 on the outer peripheral side. The two bottom blades 11 are also formed at intervals (equal intervals) in the circumferential direction so as to extend from the inner peripheral side to the outer peripheral side and intersect the tip of the outer peripheral blade 7 with an angle.

  Here, these four bottom blades 11 are substantially located on one plane perpendicular to the axis O in the rotation locus around the axis O, or slightly toward the rear end side from the plane toward the inner peripheral side. The outer peripheral edge 7 and the bottom edge 11 extend in a direction intersecting substantially orthogonally or slightly at an acute angle in the rotation trajectory. Further, as described above, the bottom blade 11 has a flat wall surface facing the front side in the end mill rotation direction T of the gash 8 on the inner peripheral side as the rake face 10 and a concave concave section in common with the outer peripheral blade 7 on the outer peripheral side. Since the rake face 6 is a rake face, as shown in FIG. 3, in the axial front end view, it extends linearly on the inner peripheral side and forms a concave curve that is recessed with respect to this straight line on the outer peripheral side. Yes.

  Of the four gashes 8 formed at the tip of the four chip discharge grooves 4, every other two gashes 8A in the circumferential direction are the remaining two adjacent to the front side in the end mill rotation direction T. The rake face 10 and the tip flank 9 on the inner peripheral side of the bottom blade 11 of the gash 8B are formed so as to cut out and extend so as to communicate with the gash 8B. On the other hand, the remaining two gashes 8B do not communicate with the gashes 8A adjacent to the end mill rotation direction T side, and the tip flank 9 is located between the bottom blades 11 formed on these gashes 8A. It is formed to remain.

  Therefore, the bottom blades 11 of the two gashes 8A, which are not in communication with the gash 8B adjacent to the rear side in the end mill rotation direction T, of the bottom blades 11 opposite to each other from the tip of the outer peripheral blade 7 toward the inner peripheral side. The end flank surfaces 9 extend to a position where they intersect, and the end mill body 1 has a long bottom blade 11A extending beyond the axis O at the end. Further, the remaining two bottom blades 11 other than the long bottom blade 11A are short bottom blades 11B whose inner peripheral ends are positioned on the outer peripheral side at a distance from the axis O at the end of the end mill main body 1. The blades 11 </ b> A and the short bottom blades 11 </ b> B are alternately arranged in the circumferential direction, and the end mill body 1 is formed to be 180 ° rotationally symmetric with respect to the axis O.

  On the other hand, as shown in FIG. 6, a twist angle gradually decreasing portion 7A is formed at the distal end portion of the outer peripheral blade 7 so that the twist angle θ with respect to the axis O of the outer peripheral blade 7 gradually decreases toward the distal end side. The twist angle gradually decreasing portion 7A has a concave curved shape in which the rake face 6 of the outer peripheral blade 7 connected to the torsion angle gradually decreasing portion 7A is recessed to the rear side in the end mill rotation direction T as described above in a cross section perpendicular to the axis O. In the cross section along the circumferential direction of the end mill body 1, that is, the cross section by the cylindrical surface centered on the axis O, the end mill rotation direction T gradually increases toward the tip side while drawing a convex curve that protrudes forward in the end mill rotation direction T. The rake face 6 and the outer peripheral flank 5 intersect each other, so that the torsion angle θ gradually decreases toward the distal end side.

  Further, a constant torsion angle portion 7B in which the torsion angle θ gradually decreasing toward the front end side is constant is formed on the distal end side of the torsion angle gradually decreasing portion 7A, and the outer peripheral blade 7 in the constant torsion angle portion 7B. Is set to a range of 0 ° to 20 ° in the present embodiment. That is, in the constant twist angle portion 7B, the cross section along the circumferential direction of the rake face 6 is in contact with the convex curve formed by the same cross section in the twist angle gradually decreasing portion 7A and gradually extends in the end mill rotation direction T toward the tip side. Or a straight line extending parallel to the axis O, and the rake face 6 and the outer peripheral flank 5 intersect to form the constant twist angle portion 7B.

  The outer peripheral blade 7 includes a cylindrical surface with a constant outer diameter centered on the axis O as described above, including the twist angle gradually decreasing portion 7A and the constant twist angle portion 7B. Has been. Further, the outer peripheral flank 5 has a cylindrical surface margin with an outer diameter equal to the outer diameter of the outer peripheral blade 7 from such an outer peripheral blade 7 toward the rear side in the end mill rotation direction T, and gradually the end mill body 1. It is formed so as to recede to the inner peripheral side.

  Accordingly, in the square end mill configured as described above, the outer peripheral blade 7 is formed in the twist angle gradually decreasing portion 7 as in the cross section along the circumferential direction of the rake face 6 as shown in FIG. It is formed so as to gradually extend in the end mill rotation direction T as it goes toward the tip side while drawing a convex curve that is convex to the side, and faces the front side in the end direction of the Gash end mill rotation like the square end mills described in Patent Documents 1 and 2. Corners due to the wall surface intersecting the outer flank face are not formed.

  Further, by gradually decreasing the twist angle θ in this way, even if the twist angle θ is strongly twisted on the rear end side of the end mill main body 1, the rake face 6 and the tip of the outer peripheral portion of the bottom blade 11 connected to the tip portion of the outer peripheral blade 7. The crossing angle with the flank 9, that is, the blade angle of the bottom blade 11 at the outer peripheral portion can be ensured to be large, and the cutting blade strength can be improved. Accordingly, it is possible to prevent the bottom blade 11 from being chipped during cutting or to prevent the outer peripheral blade 7 from being chipped at the corners as described above, thereby extending the end mill life.

  On the other hand, the outer peripheral blade 7 includes a cylindrical shape having a constant outer diameter around the axis O including the torsional angle gradually decreasing portion 7A and the aforementioned torsional angle constant portion 7B. Even when the twist angle gradually decreasing portion 7A and the constant twist angle portion 7B are formed at the intersecting ridge line portion with the flank 5, the outer peripheral blade 7 is inclined toward the inner peripheral side of the end mill body 1 as it goes to the tip side. The outer diameter is not reduced, and high-precision processing can be performed. Further, the outer peripheral flank 5 gradually moves toward the inner peripheral side of the end mill body 1 from the outer peripheral blade 7 including the twist angle gradually decreasing portion 7A and the constant twist angle portion 7B toward the rear side in the end mill rotation direction T without having a margin. Since the clearance angle is given so as to face, cutting resistance can be reduced.

  In order to form the outer peripheral blade 7 having the constant outer diameter having the torsion angle gradually decreasing portion 7A and the constant twist angle 7B on the outer peripheral flank 5 having no margin as described above, The reference line of the outer peripheral edge 7 is set so that the rake face 6 formed so as to be constant after the torsion angle θ gradually decreases toward the tip side with respect to the cylindrical surface having the same outer diameter. The outer peripheral flank 5 may be formed so as to gradually recede toward the inner peripheral side of the end mill main body 1 toward the rear side in the end mill rotation direction T with respect to the reference line.

  As described above, in this embodiment, the constant torsion angle portion 7B in which the gradually decreased torsion angle θ is constant is formed further on the distal end side of the torsion angle gradually decreasing portion 7A of the outer peripheral blade 7. Since the range in which the blade angle of the blade 11 is increased extends from the bottom blade 11 with a certain width, it is possible to more reliably prevent the bottom blade 11 from being damaged. However, in this embodiment, the constant twist angle portion 7B is formed in this way, but the outer peripheral blade 7 intersects the bottom blade 11 while the twist angle θ gradually decreases in the twist angle gradually decreasing portion 7A. Also good.

  Furthermore, in this embodiment, the torsion angle θ at the tip of the outer peripheral blade 7 gradually decreased by the torsion angle gradually decreasing portion 7A is in the range of 0 ° to 20 °, and this also prevents the bottom blade 11 from being broken. Cutting resistance can be reduced. That is, when the twist angle θ at the tip of the outer peripheral blade 7 becomes a negative angle less than 0 °, the sharpness of the bottom blade 11 may be dulled and the cutting resistance may be increased. Conversely, when the twist angle θ exceeds 20 °, the bottom blade There is a risk that it will be difficult to reliably prevent defects and the like because the 11 tool angle cannot be secured.

DESCRIPTION OF SYMBOLS 1 End mill main body 3 Cutting edge part 4 Chip discharge groove 5 Outer periphery flank 6 Rake face (Wall faced to the front side in the end mill rotation direction T of the chip discharge groove 4)
7 Peripheral blade 7A Twist angle gradually decreasing portion 7B Constant twist angle portion 8 Gash 9 Tip clearance surface 10 Rake surface of bottom blade 11 (wall surface facing front side of end mill rotation direction T of gash 8)
11 Bottom blade 11A Long bottom blade 11B Short bottom blade O End mill body 1 axis T End mill rotation direction θ Twist angle of outer peripheral blade 7

Claims (3)

A chip discharge groove is formed on the outer periphery of the end portion of the end mill body that is rotated about the axis, and extends toward the rear side in the end mill rotation direction toward the rear end side. The wall surface facing the front side in the end mill rotation direction has a concave curve shape recessed in the rear side in the end mill rotation direction in the cross section perpendicular to the axis, and the cross ridge line portion between the wall surface and the outer peripheral flank of the end mill body has a cross section. An outer peripheral blade having the concave curved wall surface as a rake face is formed, and the rake face having a concave curved section is left on the outer peripheral side of the tip portion of the chip discharge groove, the intersection ridge line between the outer peripheral portion and the tip flank of the end mill body, said peripheral cutting edge as cutting face in common the rake face of the outer peripheral cutting edge at the outer peripheral side of the end mill body A bottom blade that intersects the tip portion with an angle is formed, and a tip portion of the outer peripheral blade is formed with a torsion angle gradually decreasing portion that gradually decreases as the torsion angle of the outer peripheral blade with respect to the axis line moves toward the tip side. The outer peripheral blade has a cylindrical surface with a constant outer diameter centered on the axis including the gradually decreasing portion of the twist angle, and the outer peripheral flank is end mill rotated from the outer peripheral blade. A square end mill, wherein the square end mill is formed so as to gradually recede toward the inner peripheral side with respect to the rotational trajectory around the axis of the outer peripheral blade toward the rear side in the direction.   A constant torsion angle portion having a constant torsion angle is formed on the tip side of the torsion angle gradually decreasing portion, and the outer peripheral blade includes a rotation angle around the axis including the constant torsion angle portion. The square end mill according to claim 1, wherein the square end mill has a cylindrical surface shape with a constant outer diameter centered at the center.   The square end mill according to claim 1 or 2, wherein a twist angle at a tip of the outer peripheral blade is in a range of 0 ° to 20 °.

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