JP6036487B2 - Ball end mill - Google Patents

Description

  The present invention relates to a ball end mill in which a plurality of bottom blades having a hemispherical rotation trajectory around the axis are formed at the distal end of an end mill main body rotated about an axis at intervals in the circumferential direction.

  As a ball end mill having a plurality of blades, for example, FIG. 6 of Patent Document 1 has a plurality of (four) outer peripheral blades formed at intervals on the outer periphery of the end mill body, and rotates at the tips of these outer peripheral blades. One having an arcuate bottom blade with a hemispherical locus has been proposed.

Japanese Patent Laid-Open No. 2001-25915, FIG.

  As described above, in a ball end mill having a plurality of bottom blades having three or more blades, the gash width that becomes a pocket for discharging chips cannot be widened, resulting in poor chip discharge.

In addition, in this type of ball end mill, another reason for the deterioration of chip discharge performance is that the chips generated by the bottom blade during cutting first face a wall surface (hereinafter referred to as the gash of the gash) facing the rear side of the end mill rotation direction. The wall on the back side of the gasche is usually finished to the extent that irregularities cannot be detected with the naked eye, and the hot chips immediately after the generation are It comes into close contact when contacting the wall surface on the back side, and the chip separation from the wall surface on the back side becomes worse.
In extreme cases, high-temperature chips immediately after generation may contact and weld to the wall surface on the back side of the gasche.

    The present invention has been made under such a background, and even if the gash width is narrow, the chips generated by the bottom blade can be discharged smoothly without causing chip clogging. In addition, it is an object of the present invention to provide a ball end mill that can prevent chips from being welded to the gash wall surface.

In order to solve the above problems, the present invention provides a plurality of bottom blades having a hemispherical shape in which a rotation locus around the axis is centered on the axis at the tip of the end mill body rotated around the axis. A ball end mill formed so as to extend from the inner peripheral side of the front end portion to the outer peripheral side of the rear end with an interval in the circumferential direction, wherein a rear side in the end mill rotation direction of the gasche provided at the front end portion of the end mill body A streak whose cross section is uneven is formed on the facing wall surface, and the streak is formed such that the pitch of the unevenness increases from the base end side to the front end side of the gasche .
In the present invention, a plurality of bottom blades having a hemispherical shape in which a rotation locus around the axis is centered on the axis are provided at the tip of the end mill body rotated about the axis. A ball end mill formed so as to extend from the side to the rear end outer peripheral side with a space in the circumferential direction, and a cross section is formed on a wall surface facing the rear side in the end mill rotation direction of the gasche provided at the tip of the end mill body. Convex and concave streaks are formed, and the streaks are formed so as to extend radially around the radial intermediate portion of the bottom blade in the axial front end view.
In the present invention, a plurality of bottom blades having a hemispherical shape in which a rotation locus around the axis is centered on the axis are provided at the tip of the end mill body rotated about the axis. A ball end mill formed so as to extend from the side to the rear end outer peripheral side with a space in the circumferential direction, and a cross section is formed on a wall surface facing the rear side in the end mill rotation direction of the gasche provided at the tip of the end mill body. Convex and concave streaks are formed, and the streaks are formed such that the pitch of the concavities and convexities increases from the base end side to the tip side of the gasche, and the streaks are bottom blades in the axial front end view. It is formed so that it may extend radially centering on the radial direction intermediate part.

  In the ball end mill configured in this way, chips generated by the bottom blade at the time of cutting first come into contact with the wall surface facing the rear side in the rotation direction of the end of the gasche, that is, the wall surface on the back side of the gasche. A streak whose cross section is uneven is formed. For this reason, compared with the conventional generally known ball end mill described in the background art, the contact area between the wall surface on the back side of the gasche and the chips becomes narrow. Therefore, it is possible to suppress the phenomenon that the high-temperature chips immediately after generation contact with the wall surface on the back side of the gasche, and as a result, the chip separation from the wall surface on the back side is excellent. Become.

In addition, the muscle shape, that is formed so that the pitch of the unevenness spreads toward the distal end side from the base end side of the gash.
Chips generated by the bottom blade at the time of cutting abut against the front end portion of the wall surface on the back side of the gasche and flow from there to the base end side of the gasche. That is, the base end side of the gasche is a place where chips pass. In this way, by reducing the pitch of the unevenness on the base end side of the wall surface on the back side of the gasche, which is a place where chips pass, compared to the tip side, it is possible to further suppress the phenomenon that chips adhere to this portion. . For this reason, the chips generated by the bottom blade can be discharged more smoothly without causing chip clogging.

In addition, the muscle-like, in the axially forward end view, that is formed so as to extend radially around the radial direction intermediate portion of the end cutting edge.
Chips generated by the bottom blade may flow at an angle of less than 90 degrees with respect to the bottom blade, rather than flowing in a direction orthogonal to the bottom blade, as the end mill itself may rotate. As described above, when the streak is formed so as to extend radially around the radial direction middle part of the bottom blade in the axial front end view, the extending direction of the unevenness in the streak is approximately the direction in which the chips flow out. It becomes possible to make it orthogonal. When the direction in which the unevenness in the streaks extends and the direction in which the chips flow out are almost orthogonal, the contact area between the back wall of the gasche and the chips can be further reduced, and as a result, the wall surface Chip separation from becomes better.

  In addition, if the direction in which the unevenness in the streaks extends and the direction in which the chips flow out are almost orthogonal, the streak unevenness increases the cutting effect of the chips, and in this respect as well, the separation of the chips from the wall surface on the back side of the gasche is increased. Become good.

  As described above, according to the present invention, it is possible to suppress a phenomenon in which high-temperature chips immediately after generation are brought into close contact with a wall surface facing the rear side in the end mill rotation direction of the gasche, and chip separation from the wall surface is improved. As a result, chips can be discharged smoothly without causing chip clogging, and even when a plurality of bottom blades having three or more blades are provided, chip clogging is prevented and resistance and load during cutting are reduced. By suppressing the increase, efficient cutting can be achieved. In addition, since it is possible to suppress a phenomenon in which high-temperature chips immediately after generation are brought into close contact with the wall surface facing the rear side in the rotation direction of the end of the gash, it is possible to prevent chips from being welded to the gash wall.

It is a side view which shows one Embodiment of this invention. It is a perspective view which shows one Embodiment of this invention. It is a front view showing one embodiment of the present invention. It is a front view which shows the streaks of one Embodiment of this invention. It is a graph explaining the stripe-like property of one Embodiment of this invention.

1 to 4 show a ball end mill according to an embodiment of the present invention. FIG. 1 is a side view, FIG. 2 is a perspective view, FIG. 3 is a front view, and FIG.
As shown in FIGS. 1 and 2, the end mill body 1 has a substantially cylindrical shape with the axis O as the center, the rear end side (the right side in FIG. 1) is a shank portion 2, and the front end side is a cutting edge portion 3. When the shank portion 2 is attached to the main shaft of the machine tool, the shank portion 2 is rotated in the end mill rotation direction T around the axis O, and is fed in a direction crossing the axis O. The work material is also cut out by the cutting edge portion 3.

On the outer periphery of the cutting edge portion 3, a plurality (four in this embodiment) are twisted toward the rear side in the end mill rotation direction T from the front end side to the rear end side of the end mill body 1 and toward the rear end side. A chip discharge groove 4 is formed. Further, the rotation trajectory around the axis O is located on one cylindrical surface around the axis O at the outer peripheral side ridges of the wall surfaces of the chip discharge grooves 4 facing the end mill rotation direction T. The outer peripheral blades 5 are respectively formed.
In this embodiment, the twist angle of the chip discharge groove 4 and the outer peripheral blade 5 is set to 45 ° and a relatively large angle (so-called strong twist).

    Further, a gash 6 directed toward the inner peripheral side of the tip is formed at the tip of each chip discharge groove 4 so as to cut out the wall surface facing the end mill rotation direction T, and the end mill rotation direction of these gashes 6 Arc-shaped bottom blades 7 are formed on the outer peripheral side ridges of the wall surface facing the T side so that the rotation locus around the axis O forms a convex hemispherical shape centered on the axis O. Accordingly, in the present embodiment, four bottom blades 7 are formed on the cutting edge 3 of the end portion of the end mill body 1, and four outer peripheral blades 5 connected to these bottom blades 7 are formed on the outer periphery of the tip. Will be. These bottom blades 7 are also twisted to the rear side in the end mill rotation direction T from the inner peripheral side (axis O side) of the end mill body 1 toward the outer peripheral side of the rear end along the hemispherical surface. Each is smoothly connected to the tip of the outer peripheral blade 5.

  Here, in the present embodiment, among the four bottom blades 7, a pair of bottom blades 7 positioned on opposite sides with respect to the axis O are the long bottom blades 7 </ b> A, and the remaining pair of bottom blades 7. The blade 7 has a short bottom blade 7B whose inner peripheral end 7b extends to the outer peripheral side of the rear end from a position away from the axis O when viewed from the front in the direction of the axis O relative to the inner peripheral end 7a of the long bottom blade 7A. The bottom blades 7A and the short bottom blades 7B are alternately arranged in the circumferential direction. The end mill body 1 including the long and short bottom blades 7A and 7B and the outer peripheral blades 5A and 5B connected to the rear end thereof is formed to be 180 ° rotationally symmetric with respect to the axis O.

  Further, in the present embodiment in which the number N of the bottom blades 7 and the outer peripheral blades 5 is 4 and the end mill body 1 is 180 ° rotationally symmetric with respect to the axis O, the inner peripheral end 7a of the long bottom blade 7A is viewed from the front in the direction of the axis O. The angle formed by the tangent line and the tangent line at the inner peripheral end 7b of the short bottom blade 7B located on the end mill rotation direction T side of the long bottom blade 7A is the inner peripheral end of the short bottom blade 7B when viewed from the front end of the coaxial line O direction. Is smaller than the included angle (100 ° in the present embodiment) formed by the tangent line at the inner peripheral end 7a of the bottom blade 7 (long bottom blade 7A) positioned further on the end mill rotation direction T side of the short bottom blade 7B. Is done.

As shown in FIG. 4, in this embodiment, a streak 8 having a concave-convex cross section is formed on the wall surface 6 </ b> A facing the rear side in the end mill rotation direction of the gasche 6 provided at the tip of the end mill body 1. Yes.
The streak 8 corresponds to the wall surface 6A facing the rear side in the end mill rotation direction and the short bottom blade 7B in the gash 6 corresponding to the long bottom blade 7A (gash 6 located on the front side in the end mill rotation direction of the long bottom blade 7A). It is also formed on the wall surface 6A of the gasche 6 located on the front side in the end mill rotation direction of the gasche 6.

The streak 8 is formed so as to be inclined obliquely so that the pitch of the unevenness increases from the base end side (the shank portion 2 side) of the gash 6 toward the front end side. More specifically, the streak 8 is formed so as to extend radially around the radial center of the bottom blade 7 as the center X in the front end view in the axis O direction. In this embodiment, the radial center X of the streak 8 is a position along the bottom blade 7 and a position that is offset from the center of the end mill body 1 by about 1/2 distance of the radius of the end mill body. Although not limited to this, the radial center X of the streak 8 may be an outer position along the bottom blade 7 than this position, or conversely, along the bottom blade 7. It may be an inward position.
Such a streak 8 having a concave-convex cross section can be formed by, for example, applying the end mill body 1 to the grindstone surface when the gash 6 is formed, and processing so as to leave the ground streak as it is. .

  FIG. 5 is a graph for explaining the properties of the streak 8 according to the embodiment of the present invention. The vertical axis represents the height representing the unevenness of the streak 8 and the horizontal axis represents the distance in the width direction of the unevenness of the streak 8. The measurement point of the streak-like unevenness is a part of the wall surface 6A facing the rear side in the end mill rotation direction of the gasche 6 that is returned 2 mm from the leading edge to the base end side, and this part is orthogonal to the unevenness of the streak 8. The values when scanned in the direction are shown in FIG.

Here, the uneven pitch of the streak 8 is about 0.3 mm, and the depth of the unevenness is about 0.5 μm. However, these values are merely examples, and actually, the pitch of the unevenness of the streak 8 is 0. 0.1 mm to 0.5 mm is employed, and more preferably 0.2 mm to 0.4 mm is employed.
Further, the depth of the streak-shaped irregularities is 0.3 μm to 1.0 μm, and more preferably 0.4 μm to 0.7 μm.
The surface roughness of the streak 8 of this embodiment was an arithmetic average roughness Ra of 0.097 μm and a maximum height Rz of 0.578 μm.

  In such a ball end mill, the chips generated by the bottom blade 7 during cutting first come into contact with the wall surface 6A facing the rear side in the end mill rotation direction of the gash 6, that is, the wall surface 6A on the back side of the gash. A streak 8 whose cross section is uneven is formed on the wall surface 6A. For this reason, when the chip | tip produced | generated with the bottom blade 7 contacts 6 A of wall surfaces which face the end mill rotation direction back side of the gasche 6, the contact area becomes narrow. Therefore, when the high-temperature chips immediately after generation abuts against the wall surface 6A on the back side of the gasche 6, it is possible to suppress an event of closely contacting the wall surface 6A on the back side. As a result, the chip separation from the wall surface 6A on the back side becomes good.

As a result, it becomes possible to discharge chips smoothly without causing chip clogging. Even if the chip has a plurality of bottom blades of three or more blades and has a strongly twisted chip discharge groove 4, the opening angle of the gasche Even when it is not possible to take a wide area, it is possible to achieve efficient cutting by preventing chip clogging and suppressing an increase in resistance and load during cutting.
In addition, since it is possible to suppress a phenomenon in which high-temperature chips immediately after generation are in close contact with the wall surface 6A on the back side of the gash, it is possible to prevent chips from being welded to the gash wall.

Further, in this embodiment, the streak 8 is formed obliquely so that the pitch of the unevenness increases from the base end side of the gash 6 toward the tip end side.
Here, during cutting, chips generated by the bottom blade 7 come into contact with the front end portion of the wall surface 6 </ b> A on the back side of the gash 6 and flow from there to the base end side of the gash 6. That is, the base end side of the gasche 6 is a place where chips pass. In this way, by reducing the pitch of the unevenness on the base end side of the wall surface 6A on the back side of the gasche, which is the place where the chips pass, compared to the tip side, the phenomenon that the chips adhere to this portion can be further suppressed. Can do. For this reason, the chips generated by the bottom blade 7 can be discharged more smoothly without causing chip clogging.

  Furthermore, in this embodiment, the streak 8 is formed so as to extend radially around the radial intermediate portion X of the bottom blade 7 when viewed from the front end of the end mill in the direction of the axis O. Chips generated by the bottom blade 7 may flow 90 degrees with respect to the bottom blade 7 as indicated by an arrow Y in FIG. It flows out at an angle less than degrees. Therefore, when the chips generated by the bottom blade 7 abut on the wall surface 6A on the back side of the gasche, they abut so as to be substantially perpendicular to the extending direction of the streaks 8 formed on the wall surface 6A. In this way, when the direction in which the chips flow out and the direction in which the irregularities extend in the streak 8 are approximately orthogonal, it is possible to further reduce the contact area between the chips and the wall surface 6A on the back side of the gasche. Chip separation from becomes better.

  In addition, if the direction in which the chips flow out and the direction in which the irregularities of the streaks 8 extend are substantially orthogonal, the effect of cutting off the chips due to the irregularities of the streaks 8 is enhanced, and also in this respect, from the wall surface 6A on the back side of the gasche 6 Good chip separation.

In addition, this invention is not limited to the above-mentioned embodiment, A various change can be added in the range which does not deviate from the meaning of this invention.
For example, in the above-described embodiment, the present invention has been described by taking a ball end mill having a four-blade bottom blade 7 as an example, but the present invention is not necessarily limited to one having a four-blade bottom blade 7. For example, the present invention can be applied to a ball end mill having a bottom blade having two blades, a bottom blade having three blades, or a bottom blade having five or more blades. In the case of a ball end mill having a small diameter with a radius of 1.00 mm or less, even with a two-blade bottom blade, the gash pocket becomes narrow, so that the present invention is effective. The present invention can also be applied to equally divided and unequal ball end mills. In particular, the present invention is effective in the case of a gash that is unevenly divided and has a narrow divided region.
Further, the present invention can be applied to a ball end mill with an equal lead or a ball end mill with an unequal lead.

DESCRIPTION OF SYMBOLS 1 End mill body 2 Shank part 3 Cutting edge part 4 Chip discharge groove 5 Outer peripheral blade 5A Outer peripheral blade connected to the long bottom blade 7A 5B Outer peripheral blade connected to the short bottom blade 7B Wall on the back side)
7 Bottom blade 7A Long bottom blade 7B Short bottom blade 8 Streaked O End mill body 1 axis T End mill rotation direction

Claims (3)

A plurality of bottom blades having a hemispherical shape in which the rotation trajectory around the axis is centered on the axis are spaced from the tip inner peripheral side of the tip in the circumferential direction at the tip of the end mill body rotated around the axis. A ball end mill formed so as to extend to the outer peripheral side of the rear end,
On the wall surface facing the rear side in the end mill rotation direction of the gasche provided at the tip portion of the end mill body, a streak shape with a cross section is formed ,
2. The ball end mill according to claim 1, wherein the streaks are formed such that the pitch of the unevenness increases from the base end side to the tip end side of the gasche .   A plurality of bottom blades having a hemispherical shape in which the rotation trajectory around the axis is centered on the axis are spaced from the tip inner peripheral side of the tip in the circumferential direction at the tip of the end mill body rotated around the axis. A ball end mill formed so as to extend to the outer peripheral side of the rear end,
  On the wall surface facing the rear side in the end mill rotation direction of the gasche provided at the tip portion of the end mill body, a streak shape with a cross section is formed,
  The ball end mill is characterized in that the streak shape is formed so as to extend radially around a radial intermediate portion of the bottom blade in the axial front end view.   A plurality of bottom blades having a hemispherical shape in which the rotation trajectory around the axis is centered on the axis are spaced from the tip inner peripheral side of the tip in the circumferential direction at the tip of the end mill body rotated around the axis. A ball end mill formed so as to extend to the outer peripheral side of the rear end,
  On the wall surface facing the rear side in the end mill rotation direction of the gasche provided at the tip portion of the end mill body, a streak shape with a cross section is formed,
  The streaks are formed such that the pitch of the unevenness increases from the base end side of the gasche toward the front end side,
  The ball end mill is characterized in that the streak shape is formed so as to extend radially around a radial intermediate portion of the bottom blade in the axial front end view.

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