WO2015029850A1 - クーラント穴付きエンドミル - Google Patents
クーラント穴付きエンドミル Download PDFInfo
- Publication number
- WO2015029850A1 WO2015029850A1 PCT/JP2014/071735 JP2014071735W WO2015029850A1 WO 2015029850 A1 WO2015029850 A1 WO 2015029850A1 JP 2014071735 W JP2014071735 W JP 2014071735W WO 2015029850 A1 WO2015029850 A1 WO 2015029850A1
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- WIPO (PCT)
- Prior art keywords
- end mill
- blade
- bottom blade
- outer peripheral
- rotation direction
- Prior art date
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23C—MILLING
- B23C5/00—Milling-cutters
- B23C5/28—Features relating to lubricating or cooling
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23C—MILLING
- B23C5/00—Milling-cutters
- B23C5/02—Milling-cutters characterised by the shape of the cutter
- B23C5/10—Shank-type cutters, i.e. with an integral shaft
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23C—MILLING
- B23C5/00—Milling-cutters
- B23C5/28—Features relating to lubricating or cooling
- B23C5/283—Cutting inserts with internal coolant channels
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23C—MILLING
- B23C2210/00—Details of milling cutters
- B23C2210/20—Number of cutting edges
- B23C2210/202—Number of cutting edges three
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23C—MILLING
- B23C2210/00—Details of milling cutters
- B23C2210/28—Arrangement of teeth
- B23C2210/282—Unequal angles between the cutting edges, i.e. cutting edges unequally spaced in the circumferential direction
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23C—MILLING
- B23C2210/00—Details of milling cutters
- B23C2210/40—Flutes, i.e. chip conveying grooves
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23C—MILLING
- B23C2250/00—Compensating adverse effects during milling
- B23C2250/12—Cooling and lubrication
Definitions
- the present invention relates to an end mill with a coolant hole in which a plurality of outer peripheral blades and a bottom blade are formed at a tip portion of an end mill body, and a plurality of coolant holes are formed in the end mill body to be opened at a tip of the end mill body. Is.
- Patent Document 1 discloses that among four bottom blades (tip cutting blades) of a four-blade ball end mill.
- the coolant holes are open on the tip flank of the two bottom blades.
- a bottom blade is formed at the tip along the chip discharge groove (twist groove), and the same number of lead coolant holes as the number of these chip discharge grooves extend in the end mill body, and the tip clearance of the bottom blade extends. Proposals have been made in which each surface is opened.
- Patent Document 2 also discloses a pair of long bottom blades provided near the axis along a pair of first gashes formed symmetrically with respect to the axis, and the pair of long bottoms around the axis.
- a pair of short bottom blades provided along a second gash formed so as to reach the first gash from the outer periphery symmetrically with respect to the axial center at a position 90 ° from the blade,
- a fluid supply hole (coolant hole) that has a pair of openings that open to the flank of the long bottom blade and that is provided vertically through the end mill, and a first gash that has an end on the axis side intersecting each other; While the communication area of the second gash is increased, the four holes with coolant holes having a pair of communication grooves provided to connect the intersections of the first gash and the second gash and the openings of the coolant holes are not provided. End mill with equal bottom edge It has been described.
- the size of the pocket for chip discharge by the second gash is also limited, and as described in this Patent Document 2, the intersection of the first gash and the second gash and the opening of the coolant hole Even if a communication groove is provided so as to connect, or even if the same number of coolant holes as the chip discharge groove is formed in the end mill body as described in Patent Document 1, chip clogging occurs in the second gash. May be easier.
- the present invention has been made under such a background, and in an end mill in which a long bottom blade extending longer on the inner peripheral side of the end mill body than the other bottom blades is formed at the end portion of the end mill body, the long bottom blade It is an object of the present invention to provide an end mill with a coolant hole capable of improving the discharge of chips generated by a bottom blade adjacent to the rear side in the end mill rotation direction and preventing chip clogging and performing stable cutting.
- a tip end portion of an end mill body rotated around an axis is a cutting blade portion, and the outer periphery of the cutting blade portion includes the axis line.
- a plurality of chip discharge grooves twisted toward the rear side in the end mill rotation direction toward the rear end side in the direction are formed at intervals in the circumferential direction, and these chip discharge grooves are formed on the outer peripheral side ridge portion of the wall surface facing the end mill rotation direction.
- Each outer peripheral edge is formed, and a gash is formed at the tip of the chip discharge groove, and the outer periphery is formed at a cross ridge line portion between a wall surface facing the end mill rotation direction of the gash and a tip flank of the end mill body.
- a bottom blade extending from the tip of the blade to the inner peripheral side of the end mill body is formed, and at least one first bottom blade of the bottom blades is located behind the first bottom blade in the end mill rotation direction.
- Each of the coolant holes has a coolant hole extending in the same direction as the chip discharge groove and opening at the tip of the end mill body.
- the first bottom blade and the first bottom are formed.
- An interval between the first coolant hole opening at the rear end in the end mill rotation direction of the blade and the opening in the axial direction is open at the rear end in the end mill rotation direction of the second bottom blade and the second bottom blade. It is larger than the space
- the first bottom blade that is a long bottom blade and the opening portion of the first coolant hole that opens rearward in the end mill rotation direction when viewed from the front in the axial direction.
- the interval is made larger than the interval between the second bottom blade adjacent to the rear side in the end mill rotation direction of the first bottom blade and the opening portion of the second coolant hole opened rearward in the end mill rotation direction,
- the opening of the first coolant hole can be formed close to the gash where the second bottom blade is formed.
- the coolant can be efficiently supplied from the first coolant hole toward the gash in which the second bottom blade is formed, so that the first bottom blade is a long bottom blade on the inner peripheral side of the end mill body. Even if the size of the gash on which the second bottom blade on the rear side in the end mill rotational direction is formed is limited in order to form it to extend long, the chips generated by the second bottom blade Can be reliably discharged by being pushed out into the chip discharge groove without causing clogging.
- the distance between the first bottom blade and the opening portion of the first coolant hole opened rearward in the end mill rotation direction in the axial front end view is opened rearward in the second bottom blade and the end mill rotation direction.
- the chip discharge groove and the coolant hole have the same lead.
- the hole In the cross section perpendicular to the axis of the cutting edge portion, the hole may be greatly biased toward the chip discharge groove side connected to the gash in which the second bottom blade is formed, and may extend to the rear end side of the end mill body.
- the first coolant hole is cut by making the lead of the first coolant hole larger than the lead of the second outer peripheral blade connected to the second bottom blade.
- the chip discharge groove in which the second outer peripheral blade is formed that is, the wall surface facing the rear side in the end mill rotation direction of the chip discharge groove connected to the gash in which the second bottom blade is formed.
- And can be extended so as to be relatively away from the end mill rotating direction. Therefore, even at the rounded-up portion of the chip discharge groove, the thickness of the end mill body between the first coolant hole and the wall surface of the chip discharge groove adjacent to the rear side in the end mill rotation direction is secured to prevent a decrease in rigidity. can do.
- the leads of the plurality of coolant holes formed in the end mill body are equal to each other.
- the leads of the coolant holes are connected to the cutting blades.
- all the coolant holes are adjacent to the rear end side in the end mill rotation direction as they go to the rear end side of the cutting edge part. It can extend so that it may not approach at least the wall surface which faces the end mill rotation direction back side of a discharge groove. Therefore, especially when the lead of the first coolant hole is made larger than the lead of the second outer peripheral blade as described above, the first coolant in which the gap between the opening with the first bottom blade is increased. It is possible to secure the wall thickness between all the coolant holes including the holes and the wall surface of the chip discharge groove on the rear side in the end mill rotation direction at the rear end of the cutting edge.
- the circumferential distance between the first bottom blade and the third bottom blade adjacent to the first bottom blade in the end mill rotation direction side is set to the first bottom blade and the second bottom blade.
- the distance between the cutting amount by the first bottom blade that is a long bottom blade and the cutting amount by the second bottom blade that is shorter than this can be balanced,
- the lead of the third outer peripheral blade connected to the third bottom blade larger than the leads of the first and second outer peripheral blades respectively connected to the first and second bottom blades, the end mill rotational direction rear side
- the third, first, and second outer peripheral blades that are adjacent in the circumferential direction in turn toward each other become so-called unequal leads, and the occurrence of chatter vibration can be suppressed.
- the distance between the first and third outer peripheral blades which is smaller than the distance in the circumferential direction between the first and second outer peripheral blades at the portion connected to the bottom blade, is the rear end of the cutting blade portion. Since it gradually increases as it goes to the side, the distance between the first and third outer peripheral blades and the distance between the first and second outer peripheral blades are equally spaced at the raised portion of the chip discharge groove at the rear end of the cutting edge portion. The rigidity of the end mill body can be improved.
- the lead of the first coolant hole is made larger than the lead of the second outer peripheral blade
- the leads of the plurality of coolant holes are made equal to each other
- the leads of the plurality of outer peripheral blades By setting the lead larger than the largest lead, the coolant hole leads equal to each other are at least larger than the lead of the third outer peripheral blade, and the difference is larger than the difference from the lead of the third outer peripheral blade. It becomes larger than the leads of the first and second outer peripheral blades.
- the distance between the first and third outer peripheral blades and the distance between the first and second outer peripheral blades can be made closer to the same distance as it goes toward the rear end side of the cutting edge portion.
- the circumferential interval between the first to third outer peripheral blades in the cross section perpendicular to the axis and each coolant hole located on the rear side in the end mill rotation direction can also be made closer to the equal interval. Therefore, in the rounded-up portion of the chip discharge groove, the wall thickness of the end mill body between these coolant holes and the wall surface of the chip discharge groove adjacent to the end mill rotation direction side and the end mill rotation direction rear side is equalized. As a result, it is possible to further improve the rigidity of the end mill body at the rounded-up portion.
- the present invention excludes an end mill in which a plurality of chip discharge grooves are formed in the cutting edge portion, and the outer peripheral blade, the gash, and the bottom blade are formed in the same number as the chip discharge groove, that is, a single-blade end mill, for example.
- a single-blade end mill for example.
- it can be applied to a four-blade end mill or the like in which long bottom blades and short bottom blades are alternately formed in the circumferential direction as described in Document 2, one bottom blade is a long bottom blade.
- the three-blade end mill extended to the inner peripheral side longer than the other two bottom blades adjacent to each other, that is, three pieces of the chip discharge groove, the outer peripheral blade, It is particularly suitable when applied to an end mill with a coolant hole in which a gash, the bottom blade, and the coolant hole are formed.
- the coolant is efficiently applied to the gasche formed on the rear side in the end mill rotation direction of the long bottom blade.
- Stable cutting can be performed by preventing chip clogging in the gash and ensuring chip discharge.
- FIG. 3 It is a perspective view which shows one Embodiment of this invention. It is an enlarged front view of embodiment shown in FIG. It is an enlarged side view of the cutting edge part of embodiment shown in FIG. It is an enlarged plan view of the cutting blade part of the embodiment shown in FIG.
- FIG. 4 is an enlarged ZZ sectional view in FIG. 3.
- the end mill body 1 has a substantially cylindrical outer shape centered on the axis O with a hard material such as cemented carbide, and its rear end (upper right part in FIG. 1, right part in FIGS. 2 and 3). Is a cylindrical shank portion 2 and a tip portion (lower left portion in FIG. 1, left portion in FIGS. 2 and 3) is a cutting edge portion 3.
- the shank portion 2 is gripped by the main spindle of the machine tool and rotated in the end mill rotation direction T around the axis O, and is normally fed out in a direction intersecting the axis O and the cutting edge portion 3 is used to perform grooving or shoulder cutting of a work material such as a metal material.
- first to third three chip discharge grooves 4A to 4C are formed in order toward the rear in the end mill rotation direction T.
- the wall surface 4a is formed on the outer side edge of the wall surface 4a facing the end mill rotation direction T of the chip discharge grooves 4, that is, the intersecting ridge line portion between the wall surface 4a and the outer circumferential clearance surface 5 facing the outer circumferential side of the cutting edge portion 3.
- Each of the outer peripheral blades 6 having a rake face is formed.
- the first to third outer peripheral blades 6A to 6C are formed in order toward the rear side in the end mill rotation direction T, and these first to third outer peripheral blades 6A to 6C are formed.
- the lead is equal to the first to third chip discharge grooves 4A to 4C, respectively, and twists toward the rear side in the end mill rotation direction T toward the rear end side of the end mill body 1.
- trajectory which these outer periphery blades 6 make around the axis line O is made into one cylindrical surface centering on this axis line O. As shown in FIG.
- the outer peripheral flank 5 includes a first flank 5a having a small flank angle intersecting the outer peripheral blade 6 and a second flank having a large flank angle continuous to the rear side in the end mill rotation direction T of the first flank 5a. It is formed by the flank 5b.
- each chip discharge groove 4 the wall surface 4 a facing the end mill rotation direction T of each chip discharge groove 4 is cut out toward the inner peripheral side of the end mill main body 1, so that a concave groove shape is formed.
- Gash 7 is formed. As shown in FIGS. 3 and 4, the gash 7 has a V-shape that gradually becomes wider toward the tip end as seen from the outer peripheral side of the end mill body 1, and a wall surface 7 a that faces the end mill rotation direction T and the end mill. And a wall surface 7b facing the rear side in the rotation direction T. Therefore, in the present embodiment, the first to third gashes 7A to 7C are also formed in order toward the rear side in the end mill rotation direction T at the tip portions of the first to third chip discharge grooves 4A to 4C. become.
- each said wall surface 7a which faces the end mill rotation direction T of these gashes 7 and the front end flank 8 formed by notching the front end surface of the cutting-blade part 3 by the chip discharge groove 4 and the gash 7
- the tip flank 8 also has a first flank 8a having a small flank angle that intersects the bottom blade 9, and a second flank that has a large flank angle continuous to the rear side in the end mill rotation direction T of the first flank 8a.
- the flank 8b is formed.
- the first to third three tip flank surfaces 8A to 8C are formed on the tip surface of the cutting blade portion 3 by the first to third three chip discharge grooves 4A to 4C and the gashes 7A to 7C. Will be. Note that the widths of the first clearance surfaces 8a of the first to third tip clearance surfaces 8A to 8C are equal to each other. Then, in order toward the rear of the end mill rotation direction T, the first bottom blade 9A is formed at the intersecting ridge line portion between the wall surface 7a of the first gash 7A and the first tip flank 8A, and the second gash 7B.
- a second bottom blade 9B is formed at the intersecting ridge line portion between the wall surface 7a and the second tip flank 8B, and the second ridge line 9B is formed at the intersection ridge line portion between the wall surface 7a of the third gash 7C and the third tip flank surface 8C.
- 3 bottom blades 9C are formed. That is, the end mill with a coolant hole of the present embodiment is a three-blade end mill.
- first to third bottom blades 9A to 9C have a slight trajectory on the rear end side in the direction of the axis O as the rotation trajectory around the axis O moves toward one plane perpendicular to the axis O or toward the inner peripheral side.
- the end mill of this embodiment is a square end mill in which the bottom blade 9 intersects with the outer peripheral blade 6 at a right angle or slightly at an acute angle in the rotation trajectory.
- each bottom blade 9 extends in a straight line when viewed from the front end in the direction of the axis O, and is positioned slightly on the end mill rotation direction T side with respect to a straight line passing through the axis O parallel to the bottom blade 9. It is considered to be a rising arrangement.
- the first bottom blade 9A is longer on the inner peripheral side of the end mill body 1 than the second bottom blade 9B adjacent to the rear side in the end mill rotation direction T.
- the long bottom blade extends, and in this embodiment, it extends longer to the inner peripheral side of the end mill body 1 than the third bottom blade 9C adjacent to the end mill rotation direction T side.
- the first bottom blade 9A which is a long bottom blade, extends from the tip of the first outer peripheral blade 6A to a position beyond the axis O in the radial direction of the end mill body 1 as shown in FIG. It extends.
- the third bottom blade 9C adjacent to the first bottom blade 9A in the end mill rotation direction T side is the length of the first to third bottom blades 9A to 9C toward the inner peripheral side of the end mill body 1.
- the shortest edge is the shortest.
- the second bottom blade 9B adjacent to the end mill rotation direction T side of the third bottom blade 9C, that is, the rear side of the first bottom blade 9A in the end mill rotation direction T is a first and second bottom blades that are long and short bottom blades.
- the middle bottom blade has an intermediate length between the third bottom blades 9A and 9C.
- the lengths of the first to third bottom blades 9A to 9C are formed by making the first to third gashs 7A to 7C different sizes.
- the inner peripheral portion is largely cut away so as to communicate with the third gash 7C.
- the third bottom edge 9C is formed at the intersecting ridge line portion between the wall surface 7a and the third tip flank 8C, and the second tip flank adjacent to the end mill rotation direction T side is also used.
- the inner peripheral portion of 8B is cut out to communicate with the second gash 7B.
- the size of the third gash 7C notching the second tip flank 8B is smaller than the size of the first gash 7A notching the third tip flank 8C.
- the second gash 7B in which the second bottom blade 9B is formed at the intersecting ridge line portion between the wall surface 7a and the second tip flank 8B is an end mill thereof.
- the first tip flank 8A adjacent to the rotation direction T side is not cut out until it communicates with the first gash 7A, and the first tip flank is between the first and second gashes 7A, 7B.
- the first flank 8a of 8A is left on the inner peripheral side until it exceeds the axis O when viewed from the front in the direction of the axis O. Accordingly, the first to third bottom blades 9A to 9C are thereby made long, medium, and short bottom blades, respectively.
- each coolant hole 10 is formed to have a substantially circular shape having the same inner diameter in a cross section perpendicular to the axis O.
- these coolant holes 10 are formed so as to be twisted toward the rear side in the end mill rotation direction T toward the rear end side in the axis O direction, similarly to the chip discharge groove 4 and the outer peripheral blade 6. In the direction, it passes between adjacent chip discharge grooves 4, and is opened at the tip of the cutting blade portion 3, that is, at the tip of the end mill body 1. In particular, in the present embodiment, all of these coolant holes 10 are opened in the respective tip flank 8 between the chip discharge grooves 4 at the tip of the end mill body 1.
- a first chip discharge groove 4 ⁇ / b> A connected to the first gash 7 ⁇ / b> A in which a first bottom blade 9 ⁇ / b> A having a long bottom is formed, and an end mill of the first chip discharge groove 4 ⁇ / b> A.
- the first coolant hole 10A passing between the second chip discharge groove 4B adjacent to the rear side in the rotation direction T is connected to the rear side in the end mill rotation direction T of the first bottom blade 9A which is a long bottom blade.
- An opening is made so that the entire opening is located on the second flank 8b of the first tip flank 8A.
- the second coolant hole 10B passing between the second chip discharge groove 4B and the third chip discharge groove 4C adjacent to the rear side in the end mill rotation direction T is a second tip flank 8B.
- the first and second flank surfaces 8a and 8b are opened on the boundary line.
- the distance between the first bottom blade 9A and the opening of the first coolant hole 10A in the end view in the direction of the axis O is the second adjacent to the rear side in the end mill rotation direction T of the first bottom blade 9A.
- the distance between the bottom blade 9B and the opening of the second coolant hole 10B is larger than that in the front end view in the axis O direction.
- the third coolant hole 10C passing between the third chip discharge groove 4C and the first chip discharge groove 4A adjacent to the rear side in the end mill rotation direction T is also the first coolant flank 8C.
- the second flank 8a, 8b is opened on the boundary line, but the distance between the opening and the third bottom blade 9C when viewed from the front in the axis O direction is the second bottom blade 9B and the second coolant. It is made smaller than the space
- the first, second, and third bottom blades 9A, 9B, and 9C having a long length are arranged in the order of the axis O direction between the bottom blade 9 and the coolant hole 10 on the rear side in the end mill rotation direction T.
- the interval in the front end view is increased.
- the distance between the bottom blade 9 and each coolant hole 10 adjacent to the rear side in the end mill rotation direction T in the front view of the axis O direction is, for example, the shortest distance between each bottom blade 9 and the opening edge of each coolant hole 10. It is said.
- the first to third three coolant holes 10A to 10C have the same lead and are equally spaced in the circumferential direction on one cylindrical surface centered on the axis O of the end mill body 1. Is formed. Therefore, the openings of the coolant holes 10A to 10C at the end of the end mill body 1 are also arranged at equal intervals in the circumferential direction.
- the circumferential intervals between the first to third bottom blades 9A to 9C are set to be unequal, so that in the present embodiment, the bottom blade 9 and the coolant hole 10 are separated as described above. The intervals are made different.
- the circumferential interval between the first bottom blade 9A, which is a long bottom blade, and the second bottom blade 9B, which is a middle bottom blade on the rear side in the end mill rotation direction T is equal to each other, and the third bottom blade 9C and the third bottom blade 9C It is made larger than the space
- the interval in the circumferential direction of the bottom blades 9 is, for example, the length of an arc connecting the outer peripheral ends of the bottom blades 9 adjacent to each other in the circumferential direction with the axis O as the center when viewed from the front in the axis O direction.
- the leads of the outer peripheral blade 6 connected to the outer peripheral ends of these bottom blades 9 are also of different sizes.
- the lead of the first outer peripheral blade 6A connected to the first bottom blade 9A is the smallest, that is, the torsion angle of the first outer peripheral blade 6A is maximized
- the third bottom blade The lead of the third outer peripheral blade 6C connected to the blade 9C is the largest, that is, the twist angle of the third outer peripheral blade 6C is the smallest, and the lead and the twist angle of the second outer peripheral blade 6B connected to the second bottom blade 9B.
- the leads of the first to third coolant holes 10A to 10C twisted to the rear side in the end mill rotation direction T as they go to the rear end side in the axis O direction as in the outer peripheral blades 6 are equal to each other as described above.
- the lead is larger than the largest lead, that is, more than the lead of the third outer peripheral blade 6C.
- this third outer peripheral blade is equal to 6C lead. Therefore, the lead of these coolant holes 10, especially the lead of the first coolant hole 10A, is the lead of the second outer peripheral blade 6B located on the rear side in the end mill rotation direction T and the second outer peripheral blade 6B is the wall surface 4a. It is made larger than the lead of the 2nd chip discharge groove 4B formed in this.
- the first coolant hole 10A having the largest is the rake face of the first outer peripheral edge 6A in the cross section perpendicular to the axis O as it goes toward the rear end side in the axis O direction. Relatively approaching the wall surface 4a facing the end mill rotation direction T, it is relatively distant from the wall surface 4b facing the rear side in the end mill rotation direction T of the second chip discharge groove 4B in which the second outer peripheral blade 6B is formed. Will be going.
- the second coolant hole 10B having a large interval with the bottom blade 9 (second bottom blade 9B) adjacent to the end mill rotation direction T side next is also orthogonal to the axis O as it goes to the rear end side in the axis O direction.
- the second peripheral edge 6B relatively approaches the wall surface 4a facing the end mill rotation direction T of the second chip discharge groove 4B which is the rake face of the second outer peripheral blade 6B. Less than 10A.
- the third coolant hole 10C has the same lead as the third outer peripheral blade 6C in the present embodiment, the distance between the rake face and the wall surface 4a is constant along the axis O direction. Is done.
- the circumferential interval between the adjacent outer peripheral blades 6 is the third outer peripheral blade 6 ⁇ / b> A and the third end of the end mill main body 1 on the side T in the end mill rotation direction T side, which is the smallest interval in the portion connected to the bottom blade 9 at the tip of the end mill body 1.
- the distance from the outer peripheral blade 6C gradually increases toward the rear end side in the axis O direction.
- the interval between the blades 6C gradually decreases, and the decreasing ratios are made equal to each other.
- Each chip discharge groove 4 has substantially the same cross-sectional shape and dimensions from the wall surface 4a facing the end mill rotation direction T to the wall surface 4b facing the end mill rotation direction T, and the outer peripheral blade 6 has an end mill rotation direction T rear.
- the wall surface of the first to third chip discharge grooves 4A to 4C facing the end mill rotation direction T which is the rake face of the first to third outer peripheral blades 6A to 6C. 4a and the first to third coolant holes 10A to 10C located on the rear side in the end mill rotation direction T of each wall surface 4a in the cross section orthogonal to the axis O are also made equal to each other, that is, An equal thickness t is formed between the wall surface 4 a and the coolant hole 10.
- each coolant hole 10 in the rounded-up portion of the chip discharge groove 4 has an end mill rotation direction T of each coolant hole 10 in a cross section orthogonal to the axis O of the end mill body 1 as shown in FIG.
- the wall surface 4a facing the end mill rotation direction T of the chip discharge groove 4 formed on the side, and the wall surface facing the end mill rotation direction T rear side of the chip discharge groove 4 formed on the rear side of the end mill rotation direction T of each coolant hole 10 4b is formed so as to ensure a substantially equal thickness t.
- the thickness t is the same as that of the circle C and the coolant when a circle C in contact with each coolant hole 10 from the outer peripheral side of the end mill body 1 is drawn in the cross section perpendicular to the axis O.
- the distance between the intersection point Qa between the tangent line L and the wall surface 4a and the contact point P, and the intersection point Qb and the contact point between the tangent line L and the wall surface 4b may be such that, for example, the midpoints of the intersection points Qa and Qb in the cross section are located within a circle defined by the coolant hole 10 in the tangential line L direction.
- the first bottom blade 9A which is a long bottom blade as described above, so as to extend long toward the inner peripheral side of the end of the end mill main body 1
- this first bottom blade The second gash 7B adjacent to the rear side in the end mill rotation direction T of 9A can only be formed to a position away from the axis O toward the inner peripheral side of the end of the end mill body 1, and the gash depth is increased. It becomes shallow and the capacity of the pocket for discharging chips generated by the second bottom blade 9B must be limited.
- the front end view in the axis O direction between the first bottom blade 9A and the opening portion of the first coolant hole 10A opened rearward in the end mill rotation direction T is provided. Is larger than the distance between the second bottom blade 9B and the opening of the second coolant hole 10B. Therefore, for example, the efficiency from the first coolant hole 10 toward the second gash 7B is higher than when the distance between each bottom blade 9 and the opening of the coolant hole 10 on the rear side in the end mill rotation direction T is equal. Therefore, even if the pocket capacity of the second gash 7B is small, the chips can be reliably pushed out and discharged to the second chip discharge groove 4B without being clogged, and stable. Cutting can be performed.
- the distance between the first bottom blade 9A, which is a long bottom blade, and the opening of the first coolant hole 10A on the rear side in the end mill rotation direction T in the front view in the axis O direction is 3 is larger than the distance between the bottom blade 9 ⁇ / b> C and the opening of the third coolant hole 10 ⁇ / b> C, and is the largest distance in the end mill body 1. For this reason, it is possible to achieve more reliable chip discharge from the second gash 7B toward the second chip discharge groove 4B.
- the first and third gashs 7A and 7C are extended so as to exceed the axis O on the inner peripheral side when viewed from the front in the axis O direction. Since the depth of the gash is deeper than that of the second gash 7B and communicates with the third and second gash 7C, 7B adjacent to the end mill rotation direction T side, the pocket capacity for chip discharge is sufficient. Can be secured. Accordingly, the distance between the second and third bottom blades 9B and 9C and the openings of the second and third coolant holes 10B and 10C in the front view in the direction of the axis O is the first bottom blade 9A and the first coolant hole. Even if it is made smaller than the interval with 10A, there is no possibility of chip clogging.
- the opening of the second coolant hole 10C has a circumferential interval with the third bottom blade 9C on the rear side in the end mill rotation direction T so that the first coolant hole 10A and the second coolant hole 10C Although it becomes larger than the space
- the distance between the opening of the first bottom blade 9A and the opening in the direction of the axis O is the second and third bottom blades 9B, 9C and the second, third.
- the first coolant hole 10A which is made larger than the gap between the coolant holes 10B and 10C, has a lead that is located on the rear side in the end mill rotation direction T of the first coolant hole 10 in the second outer periphery. Since it is larger than the lead of the blade 6B, the second chip discharge groove 4B in which the second outer peripheral blade 6B is formed in the cross section orthogonal to the axis O as it goes toward the rear end side in the axis O direction as described above.
- the end mill rotation direction T is relatively away from the wall surface 4b facing the rear side.
- the first coolant hole 10A has a large gap with the first bottom blade 9A at the opening to the tip flank 8 (first tip flank 8A) at the tip of the end mill body 1, and the second gash. Even if the opening is close to 7B, the distance from the wall surface 4b of the second chip discharge groove 4B is increased toward the rear end side in the axis O direction so that the chip discharge groove 4 is as in the present embodiment. In the round-up portion, it is possible to prevent the wall thickness t between the wall surface 4b and the first coolant hole 10A from being thin.
- the rigidity of the end mill main body 1 in the above-mentioned rounded-up portion can be ensured, and even if an excessive load is applied during cutting and a force that deflects the cutting blade portion 3 from this rounded-up portion acts, the end mill main body 1 can be prevented from being broken.
- the lead of the first coolant hole 10A is made larger than the lead of the first outer peripheral blade 6A and the first chip discharge groove 4A located on the end mill rotation direction T side, and accordingly.
- the first coolant hole 10A moves away from the wall surface 4b of the second chip discharge groove 4B as described above as it goes toward the rear end side in the axis O direction, the first coolant hole 10A serves as a rake face of the first outer peripheral blade 6A.
- the wall surface 4a facing the end mill rotation direction T of the one chip discharge groove 4A is relatively approached.
- the thickness t of the end mill body 1 between the wall surface 4a on the end mill rotation direction T side of the first coolant hole 10A and the wall surface 4b on the rear side in the end mill rotation direction T is surely uniform at the rounded-up portion of the chip discharge groove 4.
- the cutting edge part 3 can be formed.
- the coolant holes 10 formed in the end mill body 1 are formed so as to be twisted in the same direction by mutually equal leads, and the end mill body 1 is formed of a powder sintered alloy such as cemented carbide.
- the raw material powder of this powder sintered alloy is kneaded with a binder and extruded while being twisted from an extrusion molding device, thereby forming a cylindrical material in which spiral holes of equal leads serving as coolant holes are formed. After sintering, a chip discharge groove, a gasche, a tip flank and an outer flank are formed, and the outer peripheral blade and the bottom blade can be sharpened.
- the lead of the coolant hole 10 made equal to each other in this way is not less than the largest lead among the leads of the plurality of outer peripheral blades 6 formed in the cutting blade portion 3, and in this embodiment the largest third It is made equal to the lead of the outer peripheral blade 6C.
- all the coolant holes 10 are at least close to the wall surface 4b facing the end mill rotation direction T rear side of the chip discharge groove 4 positioned on the rear side in the end mill rotation direction T toward the rear end side in the axis O direction. Therefore, it is possible to prevent all the coolant holes 10 from having a lack of rigidity due to a decrease in thickness between the rounded-up portion and the wall surface 4b.
- the lead of the coolant hole 10 is set to such a size that the coolant hole 10 does not open to the wall surface 4 a facing the end mill rotation direction T of the chip discharge groove 4 on the rear end side of the cutting edge portion 3. Is done.
- the circumferential interval between the first bottom blade 9A, which is a long bottom blade, and the third bottom blade 9C adjacent to the end mill rotation direction T side is the end mill rotation direction T rear side.
- the amount of cutting by the first bottom blade 9A having a longer cutting edge length is made smaller than the interval in the circumferential direction between the second bottom blade 9B, which is an intermediate bottom blade adjacent to the cutting edge length. It is possible to prevent the entire end mill body 1 from reaching the end of its life due to the early wear of only the first bottom blade 9A in balance with the amount of cutting by the short second bottom blade 9B.
- the distance between the first and third bottom blades 9A and 9C is such that the third bottom blade 9C is a short bottom blade and the second bottom adjacent to the end mill rotation direction T side. Since it is made smaller than the space
- the lead of the third outer peripheral blade 6C connected to the third bottom blade 9C is the first lead.
- the leads of the second outer peripheral blades 6A and 6B are made larger, and the leads of the first and second outer peripheral blades 6A and 6B have different sizes. Accordingly, the vibration cycles when the bottom blades 9 and the outer peripheral blades 6 bite the work material are different from each other, and these vibrations cancel each other, so that the periodic vibrations act on the end mill body 1. It is possible to suppress the occurrence of so-called chatter vibration.
- the circumferential interval between the first and third bottom blades 9A and 9C is smaller than the circumferential interval between the first and second bottom blades 9A and 9B. Since the lead of the third outer peripheral blade 6C is made larger than the leads of the first and second outer peripheral blades 6A, 6B, the first and third outer peripheral blades 6A, The interval of 6C can be brought close to the interval of the first and third outer peripheral blades 6A, 6C. In addition, in the present embodiment, the lead of the second outer peripheral blade 6B connected to the second bottom blade 9B whose distance from the third bottom blade 9C is equal to the distance from the first bottom blade 9A is the first lead.
- the intervals in the circumferential direction of all the outer peripheral blades 6 are set to be equal as described above at the cut-up portion of the chip discharge groove 4. And the rigidity of the end mill body 1 can be improved.
- the leads of the plurality of coolant holes 10 are equalized as described above and the plurality of outer peripheral blades 6 are also made. Since the lead is larger than the lead of the third outer peripheral blade 6C, which is the largest lead, the end mill of the chip discharge groove 4 which is the rake face of these outer peripheral blades 6 at the rounded-up portion of the chip discharge groove 4 The distance between the wall surface 4a facing the rotation direction T and the coolant hole 10 located on the rear side in the end mill rotation direction T can also be equal to each other.
- the circumferential interval of the outer peripheral blade 6 is equal, the wall surface 4a of the chip discharge groove 4 facing the end mill rotation direction T, and the coolant hole 10 positioned on the rear side of the end mill rotation direction T. Even if the distance between the opening of each coolant hole 10 opened at the tip of the end mill body 1 and the bottom blade 9 located on the end mill rotation direction T side is different as in this embodiment, The thickness t between the coolant hole 10 and the wall surfaces 4a and 4b of the chip discharge groove 4 located on the end mill rotation direction T side and the end mill rotation direction T rear side is equal to each other in the round-up portion of the chip discharge groove 4 and Each coolant hole 10 can be made equal.
- the opening part of 10 A of 1st coolant holes is brought close to the 2nd gash 7B as mentioned above, and cutting
- the plurality of chip discharge grooves 4 are also formed at equal intervals in the circumferential direction in this rounded-up portion, good chip discharge performance is achieved in combination with the balance of the cutting amount. Obtainable.
- the wall thickness t between them is equal to each other.
- the wall thickness between the chip discharge groove 4 and the wall surface 4b is made larger than the wall thickness between the wall surface 4a of the chip discharge groove 4 on the end mill rotation direction T side, and on the rear end side of the outer peripheral blade 6. You may make it raise the intensity
- the thickness between the coolant hole 10 and the wall surface 4b in the rounded-up portion may be smaller than the wall thickness between the wall surface 4a.
- the first coolant hole 10A opens to the second flank 8b of the first tip flank 8A that is continuous with the first bottom blade 9A. You may open over the wall surface 7b which faces the end mill rotation direction T back side of the 2nd gashes 7B. In such a case, if the gap between the first bottom blade 9A and the opening of the first coolant hole 10A can be large, the opening of the second coolant hole 10B or the third coolant hole 10C is The second and third tip flank surfaces 8B and 8C may be opened only on the second flank surface 8b without straddling the first flank surface 8a.
- the second bottom blade 9B is an intermediate bottom blade
- the third bottom blade 9C is a short bottom blade.
- the second bottom blade 9B is a short bottom blade
- the bottom blade 9C may be an intermediate bottom blade
- the second and third bottom blades 9B and 9C may have the same length.
- the outer periphery blade and the bottom blade are 1
- the present invention may be applied to a radius end mill in which a convex curve shape such as a 1 ⁇ 4 arc is connected via a corner blade, or in some cases, a ball end mill in which the bottom blade itself forms a convex curve shape such as a 1 ⁇ 4 arc in a rotation locus. Is possible.
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Milling Processes (AREA)
Abstract
Description
2 シャンク部
3 切刃部
4 切屑排出溝
4A~4C 第1~第3の切屑排出溝
4a 切屑排出溝4のエンドミル回転方向Tを向く壁面
4b 切屑排出溝4のエンドミル回転方向T後方側を向く壁面
5 外周逃げ面
6 外周刃
6A~6C 第1~第3の外周刃
7 ギャッシュ
7A~7C 第1~第3のギャッシュ
8 先端逃げ面
8A~8C 第1~第3の先端逃げ面
8a 先端逃げ面8の第1逃げ面
8b 先端逃げ面8の第2逃げ面
9 底刃
9A 第1の底刃(長底刃)
9B 第2の底刃(中底刃)
9C 第3の底刃(短底刃)
10 クーラント穴
10A~10C 第1~第3のクーラント穴
O エンドミル本体1の軸線
T エンドミル回転方向
t 切刃部3後端側におけるクーラント穴10と切屑排出溝4の壁面4a、4bとの間の肉厚
Claims (5)
- 軸線回りに回転されるエンドミル本体の先端部が切刃部とされ、
この切刃部の外周には、上記軸線方向後端側に向かうに従いエンドミル回転方向後方側に捩れる複数の切屑排出溝が周方向に間隔をあけて形成され、
これらの切屑排出溝のエンドミル回転方向を向く壁面の外周側辺稜部に外周刃がそれぞれ形成されるとともに、
上記切屑排出溝の先端部にはギャッシュが形成され、
これらのギャッシュのエンドミル回転方向を向く壁面と上記エンドミル本体の先端逃げ面との交差稜線部に、上記外周刃の先端から上記エンドミル本体の内周側に延びる底刃がそれぞれ形成されており、
上記底刃のうち少なくとも1つの第1の底刃は、この第1の底刃のエンドミル回転方向後方側に隣接する第2の底刃よりも上記エンドミル本体の内周側に長く延びる長底刃とされるとともに、
上記エンドミル本体内には、周方向において隣接する上記切屑排出溝同士の間に、上記切屑排出溝と同じ向きに捩れるように延びて上記エンドミル本体の先端に開口するクーラント穴がそれぞれ形成されていて、
これらのクーラント穴のうち、上記第1の底刃と該第1の底刃のエンドミル回転方向後方側に開口する第1のクーラント穴の開口部との上記軸線方向先端視における間隔が、上記第2の底刃と該第2の底刃のエンドミル回転方向後方側に開口する第2のクーラント穴の開口部との上記軸線方向先端視における間隔よりも大きくされていることを特徴とするクーラント穴付きエンドミル。 - 上記第1のクーラント穴のリードが、上記第2の底刃に連なる第2の外周刃のリードよりも大きくされていることを特徴とする請求項1に記載のクーラント穴付きエンドミル。
- 複数の上記クーラント穴のリードは、互いに等しくされるとともに、上記切刃部に形成された複数の上記外周刃のリードのうち最も大きなリード以上とされていることを特徴とする請求項1または請求項2に記載のクーラント穴付きエンドミル。
- 上記第1の底刃と、この第1の底刃のエンドミル回転方向側に隣接する第3の底刃との周方向の間隔は、上記第1の底刃と上記第2の底刃との周方向の間隔よりも小さくされるとともに、上記第3の底刃に連なる第3の外周刃のリードが上記第1、第2の底刃にそれぞれ連なる第1、第2の外周刃のリードよりも大きくされていることを特徴とする請求項1から請求項3のうちいずれか一項に記載のクーラント穴付きエンドミル。
- 上記切刃部には、それぞれ3つずつの上記切屑排出溝、上記外周刃、上記ギャッシュ、上記底刃、および上記クーラント穴が形成されていることを特徴とする請求項1から請求項4のうちいずれか一項に記載のクーラント穴付きエンドミル。
Priority Applications (4)
Application Number | Priority Date | Filing Date | Title |
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US14/914,073 US20160214187A1 (en) | 2013-08-30 | 2014-08-20 | End mill with coolant hole |
KR1020167007941A KR20160047546A (ko) | 2013-08-30 | 2014-08-20 | 쿨런트 구멍을 갖는 엔드밀 |
EP14839052.9A EP3040146A1 (en) | 2013-08-30 | 2014-08-20 | End mill with coolant hole |
CN201480039455.2A CN105377488A (zh) | 2013-08-30 | 2014-08-20 | 带冷却孔的立铣刀 |
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JP2013-179985 | 2013-08-30 | ||
JP2013179985A JP2015047655A (ja) | 2013-08-30 | 2013-08-30 | クーラント穴付きエンドミル |
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US (1) | US20160214187A1 (ja) |
EP (1) | EP3040146A1 (ja) |
JP (1) | JP2015047655A (ja) |
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US11491594B2 (en) * | 2018-01-08 | 2022-11-08 | Ford Motor Company | Tooling assembly with internal coolant passages for machines |
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CN110394867A (zh) * | 2019-08-26 | 2019-11-01 | 南京帝鼎数控科技有限公司 | 一种有通气孔的木工切削刀具 |
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US20160214187A1 (en) | 2016-07-28 |
CN105377488A (zh) | 2016-03-02 |
KR20160047546A (ko) | 2016-05-02 |
EP3040146A1 (en) | 2016-07-06 |
JP2015047655A (ja) | 2015-03-16 |
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