JP2019005882A - drill - Google Patents

Abstract

To provide a drill in which the strength of the blade edge of the radially inside end part of a thinning cutting blade part can be improved, thereby preventing, for example, damage to a chisel, making it possible to stably carry out a highly accurate drilling process.SOLUTION: In a cutting blade 4, a thinning cutting blade part 9 located at least radially inside is a honing blade. The position where the honing width of the thinning cutting blade part 9 is maximum is radially outside the position of a length X×(1/6), which is from the radially inside end of the thinning cutting blade part 9 to the radially outside end thereof, if the blade length of the thinning cutting blade part 9 is X, and is radially inside the position of a length X×(1/3). The maximum value of the honing width of the thinning cutting blade part 9 is equal to or greater than 1.5 times of the honing width, at the radially outside end, of the thinning cutting blade part 9.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a drill in which a honing process is performed on a cutting edge.

  Conventionally, for example, a drill in which a honing process is performed on a cutting blade to form a honing blade as shown in Patent Document 1 below is known. The drill of Patent Document 1 includes, as cutting edges, a thinning cutting edge portion located in the radially inner portion (inner peripheral portion), and a main cutting edge portion located radially outside the thinning cutting edge portion. I have. The honing width of the thinning cutting edge is maximized at the radially outer end of the thinning cutting edge (connecting portion with the main cutting edge), and gradually increases from the radial outer end toward the radial inner side. Get smaller.

Japanese Patent Laying-Open No. 2006-2617

  However, in the conventional drill, the strength of the blade edge at the radially inner end portion (near the axis) of the thinning cutting edge portion is not secured, and there is a possibility that the chisel is broken.

  The present invention has been made in view of such circumstances, and can increase the strength of the blade edge at the radially inner end portion of the thinning cutting edge portion, thereby preventing chipping and the like from being highly accurate. An object of the present invention is to provide a drill capable of performing stable drilling.

  A drill according to an aspect of the present invention has an axial shape, a drill main body that is rotated in a drill rotation direction in a circumferential direction around the axis, and an outer periphery of the drill main body, from the front end to the rear end side in the axial direction. A chip discharge groove extending toward the edge, a cutting edge formed at a crossing ridge line portion of the tip surface of the drill body and a wall surface facing the drill rotation direction of the chip discharge groove, the tip surface, and the drill rotation of the tip surface A thinning surface formed between the chip discharge groove adjacent to the direction opposite to the direction, and a thinning cutting edge portion located at least in a radially inner portion perpendicular to the axis among the cutting edges Is a honing blade, and the position where the honing width is maximum in the thinning cutting edge portion is X from the blade length of the thinning cutting edge portion to the radial outer end from the radial inner end of the thinning cutting edge portion. The radial direction of the thinning cutting edge portion is radially outer than the position of the directed length X × (1/6) and radially inner than the position of the length X × (1/3). The maximum value of the honing width of the thinning cutting edge portion is 1.5 times or more with respect to the honing width at the outer end.

  In the drill of the present invention, the thinning cutting edge portion of the cutting edge is subjected to honing treatment, and the thinning cutting edge portion is a honing blade. The honing width of the thinning cutting edge portion is the radial outer end of the thinning cutting edge portion (that is, the connecting portion between the thinning cutting edge portion and the main cutting edge portion located radially outside the thinning cutting edge portion). However, the maximum value is at the radially inner end. Specifically, the position where the honing width is maximum in the thinning cutting edge is the position of the length X × (1/6) from the radially inner end to the outer end of the cutting length X of the thinning cutting edge. And a position of length X × (1/3).

The portion of the thinning cutting edge that has the maximum honing width is located radially inward from the position of the length X × (1/3) from the radial inner end. It is possible to improve the strength of the blade edge at the radially inner end (near the axis), and it is possible to remarkably prevent the chipels connected to the radially inner end from being damaged.
In other words, it is possible to secure a sufficient honing width at the radially inner end of the thinning cutting edge, which tends to have insufficient cutting edge strength due to the high cutting load, and this increases the rigidity of the drill tip, resulting in high-precision drilling. Can be performed stably.

  Moreover, the thinning cutting edge part is located on the outer side in the radial direction from the position of the length X × (1/6) from the radial inner end of the thinning cutting edge part. This makes it possible to improve the manufacturability of the drill (particularly the formability at the radially inner end (innermost end) of the thinning cutting edge portion) while reliably increasing the edge strength at the radially inner end. In addition, since the honing width of the thinning cutting edge is not the maximum at the radially inner end of the thinning cutting edge, the rigidity of the drill tip is reduced to increase the honing width at the radially inner end. Therefore, it is possible to stably prevent the chisel from being lost by securing the rigidity of the drill tip.

  Moreover, since the maximum value of the honing width (maximum honing width) of the thinning cutting edge is 1.5 times or more on the basis of the honing width at the radially outer end of the thinning cutting edge, the thinning cutting edge The blade edge strength at the radially inner end can be reliably increased, and the above-described effects are stably achieved.

  As described above, according to the present invention, the edge strength of the inner end portion in the radial direction of the thinning cutting edge portion can be reliably increased, thereby preventing the chipel from being damaged and the like, and highly accurate drilling can be stably performed over a long period of time. Can be done.

  In the drill, it is preferable that a rake angle of the thinning cutting edge portion is constant over the entire length of the thinning cutting edge portion.

  In this case, as described above, the sharpness of the thinning cutting edge can be increased uniformly over the entire length of the cutting edge while increasing the strength of the cutting edge of the thinning cutting edge.

  In the drill, the maximum value of the honing width of the thinning cutting edge portion is preferably 2.5 times or less of the honing width at the radially outer end of the thinning cutting edge portion.

  If the maximum honing width of the thinning cutting edge is 2.5 times or less on the basis of the honing width at the radially outer end of the thinning cutting edge as in the above configuration, the blade length of the thinning cutting edge It is possible to prevent the honing width from changing too much in the region. This prevents a large cutting load from acting locally on the thinning cutting edge during cutting (that is, the cutting load on the cutting edge can be substantially equalized over the entire length of the blade), and the rigidity of the tip of the drill is secured. The In addition, the ease of manufacturing the thinning cutting edge portion is also favorably maintained.

  Further, in the drill, the drill is a twist drill, and the drill body is formed with a pair of the front end surface and the thinning surface, and the drill body is viewed from the front end in the axial direction toward the rear end side. In the front view of the drill, the intersecting ridge line between the tip surface and the thinning surface is a straight line, and an extended line extending the first intersecting ridge line toward the second intersecting ridge line among the pair of intersecting ridge lines. Is preferably arranged on the second intersecting ridge line or on the opposite side of the drill rotation direction from the second intersecting ridge line.

  In this case, the ratio of the thinning surface tends to increase with respect to the tip surface (tip flank surface), and since the thinning surface is formed large, chip discharge is excellent and cutting resistance is reduced. In addition, a large space on the rake face at the inner end in the radial direction of the thinning cutting edge (the space that becomes the chip pocket of the thinning cutting edge) can be secured, especially in the vicinity of the chisel. Can be improved. Thereby, the precision of drilling is stably improved.

  In the drill, an extended line extending from the first intersecting ridge line toward the second intersecting ridge line out of the pair of intersecting ridge lines is on the opposite side of the drill rotation direction from the second intersecting ridge line. It is preferable that a distance along the circumferential direction between the extended line and the second intersecting ridge line is 0.04 mm or less.

  If the distance along the circumferential direction between the extended line of the first intersecting ridge line and the second intersecting ridge line is 0.04 mm or less as in the above configuration, the area ratio of the thinning surface as described above It is possible to prevent the chisel rigidity from being reduced and to maintain good drill tip rigidity while increasing the chip discharge performance.

  Further, in the drill, the cutting edge has a main cutting edge portion connected to a radially outer side of the thinning cutting edge portion, the main cutting edge portion is a honing blade, and the honing of the main cutting edge portion The width is preferably constant over the entire length of the main cutting edge.

  In this case, the main cutting edge portion of the cutting edge is subjected to honing treatment, and the main cutting edge portion is also a honing blade. That is, since the cutting edge is subjected to the honing process over the entire cutting edge length, the cutting edge strength of the cutting edge is enhanced over the entire cutting edge length. In addition, since the honing width of the main cutting edge is constant over the entire length of the main cutting edge, manufacturing of the drill is easy.

  Further, in the drill, it is preferable that a concave portion is formed at a radially inner end portion of the thinning surface.

  In this case, chip clogging in the vicinity of the chisel can be prevented by temporarily holding the chip generated by cutting the workpiece by the thinning cutting edge part and discharging it. That is, the chip discharging property near the thinning cutting edge is improved, and the accuracy of drilling can be improved.

  According to the drill of the present invention, it is possible to increase the strength of the edge of the radially inner end of the thinning cutting edge, thereby preventing the chisel from being damaged and performing highly accurate drilling stably. it can.

It is a front view of a drill concerning one embodiment of the present invention. It is a top view (side view) of the drill which concerns on one Embodiment of this invention. It is a front view which expands and shows the principal part of a drill. It is a top view (side view) which expands and shows the principal part of a drill. It is a perspective view which expands and shows the principal part of a drill. It is a blade-tip enlarged view which shows a cross section perpendicular | vertical to the blade length direction of a thinning cutting blade part (cutting blade).

  Hereinafter, a drill 10 according to an embodiment of the present invention will be described with reference to the drawings. Note that the drawings used for describing the embodiments of the present invention may show enlarged, emphasized, and excerpted parts that are essential parts in order to make the features of the present invention easier to understand. The ratio is not always the same as the actual one.

  As shown in FIGS. 1 and 2, the drill 10 of the present embodiment has a drill body 1 having an axial shape. The drill body 1 has a first end portion along the axis O direction as a blade portion, and a portion other than the first end portion including the second end portion along the axis O direction (that is, a portion other than the blade portion). ) Is a shank portion (not shown).

  The shank portion of the drill main body 1 is detachably mounted on, for example, a main shaft of a machine tool or a drilling machine. The drill body 1 is rotated in the drill rotation direction T in the circumferential direction around the axis O with respect to the work material, and is sent out in the direction of the axis O, and cut into the work material by the blade portion to perform drilling.

The definition of the direction (direction) used in the present embodiment is as follows.
The direction along the axis O of the drill body 1 (the direction in which the axis O extends) is referred to as the axis O direction. Of the axis O direction, the direction from the shank part of the drill body 1 to the blade part (upper side in FIG. 2) is referred to as the front end side, and the direction from the blade part to the shank part (lower side in FIG. 2) is the rear end side. That's it.
A direction orthogonal to the axis O is referred to as a radial direction. Of the radial directions, a direction approaching the axis O is referred to as a radial inner side, and a direction away from the axis O is referred to as a radial outer side.
A direction that circulates around the axis O is referred to as a circumferential direction. Of the circumferential directions, the direction in which the drill body 1 is rotated during drilling is referred to as a drill rotation direction T, and the opposite rotation direction is referred to as the opposite side of the drill rotation direction T (the anti-drill rotation direction).

  A plurality of chip discharge grooves 2 extending from the front end in the axis O direction toward the rear end side are formed on the outer periphery of the drill body 1 at intervals in the circumferential direction. The chip discharge groove 2 opens at the tip of the drill body 1 and gradually twists toward the opposite side of the drill rotation direction T from the tip toward the rear end side in the axis O direction and extends in a spiral shape. .

The plurality of chip discharge grooves 2 are arranged at equal intervals (at equal pitches) in the circumferential direction on the outer periphery of the drill body 1 so as to be rotationally symmetric with respect to the axis O. As shown in FIG. 1, the chip discharge groove 2 has a concave curved inner surface.
In the example of the present embodiment, the drill 10 is a twist drill, and two chip discharge grooves 2 are formed on the outer periphery of the drill body 1. In association therewith, a tip surface 3, a cutting edge 4, a thinning surface 5 and a land portion 15 (to be described later) of the drill body 1 are also formed in pairs (each pair).

  Although not shown, the chip discharge groove 2 is cut in the outer peripheral surface of the drill body 1 toward the radially outer side, for example, in a region located on the rear end side from the vicinity of the center of the drill body 1 in the axis O direction. It is up. And in the drill main body 1, the range in which the chip | tip discharge groove | channel 2 along the axis line O direction was formed is made into a blade part, and the site | part of the rear end side from this range is made into the shank part.

  1 and 2, the tip of the drill body 1 has a tip surface (tip flank) 3 facing the tip side (drill feed direction) of the drill 10 and a wall surface facing the drill rotation direction T of the chip discharge groove 2. 2a and the cutting edge 4 formed at the intersecting ridge line part of the tip surface 3, and the tip discharge surface 2 formed between the tip surface 3 and the chip discharge groove 2 adjacent to the side opposite to the drill rotation direction T. A thinning surface 5. The thinning surface 5 is a surface (inclined surface) facing the front end side in the direction of the axis O and the anti-drill rotation direction among the thinning portions formed so as to cut out the front end portion of the chip discharge groove 2 in the drill body 1.

The tip surface (tip flank) 3 includes a first tip flank 6 disposed adjacent to the side opposite to the drill rotation direction T of the cutting edge 4 and a side opposite to the drill rotation direction T of the first tip flank 6. And a second tip flank 7 disposed adjacent thereto.
The first tip flank 6 is gradually inclined toward the rear end side in the axis O direction as it goes from the cutting edge 4 toward the side opposite to the drill rotation direction T. The second tip flank 7 is gradually inclined toward the rear end side in the axis O direction from the first tip flank 6 toward the opposite side of the drill rotation direction T from the first tip flank 6. Also has a large clearance angle. That is, the displacement amount in the direction of the axis O per unit length along the circumferential direction of the drill in the second tip flank 7 (the inclination corresponding to the relief angle) is larger than the displacement amount in the first tip flank 6.

As shown in FIG. 1, when the drill body 1 is viewed from the front side of the drill body 1 toward the rear end side from the front end in the axis O direction, the first front end flank 6 has a strip shape extending in the radial direction (substantially longer in the radial direction). The second tip flank 7 has a fan shape.
In the example of this embodiment, the tip surface 3 has two different inclined surfaces (the first tip flank 6 and the second tip flank 7), but is not limited to this. The tip surface 3 may be formed by a single inclined surface, or may be provided with three or more inclined surfaces.

  A coolant hole 8 is opened in the distal end surface 3. The coolant hole 8 extends by twisting the inside of the drill body 1 along the chip discharge groove 2 and is formed so as to penetrate the drill body 1 in the direction of the axis O. In the coolant hole 8, for example, coolant (oil-based or water-soluble cutting fluid, compressed air, or the like) supplied through a main shaft of a machine tool or the like flows. The coolant is caused to flow out through the coolant hole 8 of the drill body 1 toward the distal end portion (blade portion) of the drill body 1 and the processing portion of the work material.

  In the example of this embodiment, the coolant hole 8 opens on the second tip flank 7 of the tip surface 3. Instead of this, or together with this, the coolant hole 8 may open to the first tip flank 6 or the thinning surface 5.

  In the front view of the drill shown in FIG. 1, the thinning surface 5 is a groove bottom portion directed radially inward from a wall surface 2 b facing away from the drill rotation direction T of the chip discharge groove 2 in the tip portion of the drill body 1. Between the concave curve part (the deepest part located in the innermost radial direction among the chip discharge grooves 2) and the tip surface 3 (second tip clearance surface 7) adjacent to the drill rotation direction T of the concave curve part. Is formed. The thinning surface 5 has a planar shape inclined so as to face the tip side in the direction of the axis O and the side opposite to the drill rotation direction T.

  The thinning surface 5 has a larger clearance angle than the tip surface 3 (the first tip flank 6 and the second tip flank 7). That is, the displacement amount (inclination corresponding to the clearance angle) in the direction of the axis O per unit length along the circumferential direction of the drill on the thinning surface 5 is larger than the displacement amount on the tip surface (tip clearance surface) 3.

  The cutting edge 4 is formed at the intersecting ridge line portion of the tip portion of the wall surface 2 a facing the drill rotation direction T of the chip discharge groove 2 and the first tip flank 6 of the tip surface 3. In FIG. 2, the cutting edge 4 extends toward the rear end side in the axis O direction as it goes radially outward. The cutting edge 4 is formed with the wall surface 2a as a rake face and the tip face 3 (first tip flank 6) as a flank.

  The cutting edge 4 includes a thinning cutting edge portion 9 positioned at a radially inner portion (inner peripheral portion) of the cutting edge 4 and a main cutting edge portion 13 connected to a radially outer side of the thinning cutting edge portion 9. Have. In the example of this embodiment, the honing process is performed over the entire length of the cutting edge 4, so that both the thinning cutting edge portion 9 and the main cutting edge portion 13 are honing blades.

  The thinning cutting edge portion 9 is formed at the intersecting ridge line portion between the thinning wall surface (thinning rake surface) indicated by reference numeral 14 in FIG. 2 and the front end surface 3 (first front end flank 6). The thinning wall surface 14 is a surface (standing wall surface) facing the drill rotation direction T among the thinning portions formed so as to cut out the tip of the chip discharge groove 2 in the drill body 1. The thinning wall surface 14 is located at the inner peripheral portion of the tip end of the wall surface 2a facing the drill rotation direction T of the chip discharge groove 2, and has a triangular surface shape.

  FIGS. 3-5 is an enlarged view which shows the principal part (thinning cutting-blade part 9 vicinity) of the drill 10 of this embodiment. FIG. 3 is a front view of the main part of the drill 10 as viewed from the front end to the rear end side in the direction of the axis O, and FIG. 4 is a plan view of the main part of the drill 10 viewed from the radial direction orthogonal to the axis O. FIG. 5 is a perspective view of a main part of the drill 10 viewed from an angle between them (an angle inclined by about 45 degrees with respect to the axis O).

As shown in FIGS. 3 to 5, the honing width of the thinning cutting edge portion 9 is increased from the radial outer end of the thinning cutting edge portion 9 toward the radial inner side. That is, in FIG. 4, the honing width of the thinning cutting edge portion 9 is determined by the thinning from the connecting portion 16 between the thinning cutting edge portion 9 and the main cutting edge portion 13 adjacent to the outside of the thinning cutting edge portion 9 in the radial direction. It gradually increases as it goes radially inward along the blade length direction of the cutting edge portion 9.
The “honing width” as used in the present embodiment is a cutting edge of honing (roundness, chamfering, etc.) formed by performing a honing process on the cutting edge 4 and extending along the blade length direction of the cutting edge 4. The length (namely, width) in the direction perpendicular to the blade length direction of 4 is indicated.

  Specifically, the honing width of the thinning cutting edge portion 9 is maximum at a predetermined portion located between the radial outer end (connection portion 16) and the radial inner end (near the axis O) of the thinning cutting edge portion 9. It becomes. The portion where the honing width of the thinning cutting edge portion 9 is maximum is located in the radially inner portion along the blade length direction of the thinning cutting edge portion 9. That is, the portion having the maximum honing width in the thinning cutting edge portion 9 is disposed radially inward from the center along the blade length direction of the thinning cutting edge portion 9. In addition, about the thinning cutting edge part 9, the honing width | variety of the part located in a radial inside rather than the part used as the maximum honing width becomes small as it goes to a radial inside.

  In FIG. 4, the position where the honing width is maximum in the thinning cutting edge portion 9 is X from the blade length of the thinning cutting edge portion 9 to the radially outer end of the thinning cutting edge portion 9. It is radially outward from the position of the directed length X × (1/6) and radially inward from the position of length X × (1/3). That is, the portion (the predetermined portion) having the maximum honing width in the thinning cutting edge portion 9 is the radially inner end of the thinning cutting edge portion 9 when the cutting length X of the thinning cutting edge portion 9 is divided into six equal parts. Is set to a range of length X × (1/6) to length X × (2/6) from the end to the outer end.

  Further, the maximum value of the honing width of the thinning cutting edge portion 9 is 1.5 times or more with respect to the honing width at the radially outer end (connecting portion 16) of the thinning cutting edge portion 9, preferably 2. 5 times or less. That is, when the honing width at the radially outer end of the thinning cutting edge portion 9 is defined as a reference value (= 1), the maximum honing width of the thinning cutting edge portion 9 is 1.5 times the reference value. More than 2.5 times. Moreover, in the example of this embodiment, the honing width | variety of the thinning cutting-blade part 9 is 50 micrometers or more and 100 micrometers or less.

In the present embodiment, the rake angle of the thinning cutting edge portion 9 is constant over the entire length of the thinning cutting edge portion 9.
FIG. 6 is an enlarged view of the blade tip showing a cross section perpendicular to the blade length direction of the thinning cutting edge portion 9. As shown in FIG. 6, the thinning cutting edge portion 9 includes a straight portion 17 that inclines toward the drill rotation direction T from the front end in the axis O direction toward the rear end side (downward in FIG. 6), and the straight portion 17. And the convex curve portion 18 that smoothly connects the first tip flank 6 (tip surface 3), and the straight portion 17 and the thinning wall surface 14 (the wall surface 2a facing the drill rotation direction T of the chip discharge groove 2) smoothly. And a convex curve portion 19 to be connected. That is, the thinning cutting edge portion 9 of the present embodiment is a composite honing formed by combining Chamfa honing and round honing. The microscopic rake angle of the thinning cutting edge portion 9 set according to the inclination of the straight line portion 17 is also constant over the entire length of the thinning cutting edge portion 9.

  3 to 5, what is indicated by reference numeral 20 is a recess located at the radially inner end of the thinning surface 5. The concave portion 20 is formed so as to be recessed toward the rear end side in the axis O direction from the portion around the concave portion 20 on the thinning surface 5. For example, when the thinning cutting edge portion 9 is subjected to honing with a grinding wheel, the concave portion 20 is given a shape at the tip of the drill together with honing. In the front view of the drill shown in FIG. 3, the concave portion 20 has a triangular surface shape, and, of the thinning surface 5, the corner portion (corner portion) where the thinning cutting edge portion 9 intersects an intersecting ridge line R described later. Has been placed.

  In FIG. 1 and FIG. 2, the main cutting edge portion 13 includes a portion of the wall surface 2 a facing the drill rotation direction T of the chip discharge groove 2, and a first tip clearance surface 6, which is positioned radially outward from the thinning wall surface 14. It is formed at the intersection ridge line part with (tip surface 3). The main cutting edge portion 13 is smoothly connected to the radially outer end of the thinning cutting edge portion 9 without a step, and extends from the connection portion 16 toward the radially outer side.

In the front view of the drill shown in FIG. 1, the main cutting edge portion 13 has a concave curve shape. Further, the blade length of the main cutting edge portion 13 is longer than the blade length of the thinning cutting edge portion 9 and occupies half or more of the total cutting edge length of the cutting edge 4.
As shown in FIGS. 1 and 2, the honing width of the main cutting edge portion 13 is constant over the entire blade length of the main cutting edge portion 13. The honing width of the main cutting edge portion 13 is equal to the honing width at the radially outer end of the thinning cutting edge portion 9.

  Although not shown, the main cutting edge portion 13 includes the straight line portion 17 and the convex curve portions 18 and 19 in a cross-sectional view perpendicular to the blade length direction, similarly to the thinning cutting edge portion 9. That is, the straight line portion 17 and the convex curve portions 18 and 19 are formed over the entire blade length of the cutting edge 4.

  As shown in FIGS. 1 and 3, the front end surface 3 (the second front end flank 7) and the thinning surface 5 are viewed from the front of the drill when the drill body 1 is viewed from the front end in the axis O direction toward the rear end. The intersecting ridge line R with the straight line shape. In FIG. 3, of the pair of intersecting ridge lines R, an extension line (virtual straight line) L extending the first intersecting ridge line (one intersecting ridge line) R1 toward the second intersecting ridge line (the other intersecting ridge line) R2 is Are arranged so as to coincide with the second intersecting ridgeline R2 or adjacent to the opposite side of the drill rotation direction T from the second intersecting ridgeline R2.

  In the present embodiment, of the two intersecting ridgelines R1 and R2, the extended line L extending the first intersecting ridgeline R1 toward the second intersecting ridgeline R2 is rotated by drilling more than the second intersecting ridgeline R2. It is arrange | positioned on the opposite side to the direction T, and the distance A along the circumferential direction between this extension line L and 2nd intersection ridgeline R2 is 0.04 mm or less.

In FIG.1 and FIG.2, the land part 15 is formed between the chip | tip discharge grooves 2 adjacent to the circumferential direction among the outer periphery of the drill main body 1. FIG.
The land portion 15 includes a first margin portion 11 disposed adjacent to the opposite side to the drill rotation direction T of the wall surface 2 a facing the drill rotation direction T of the chip discharge groove 2, and the drill rotation direction T from the first margin portion 11. And a second margin portion 12 disposed away from the first margin portion 11 on the opposite side. That is, the drill 10 of this embodiment is a double margin type drill. In the illustrated example, the second margin portion 12 is disposed adjacent to the drill rotation direction T of the wall surface 2b facing the opposite side to the drill rotation direction T of the chip discharge groove 2 (that is, disposed adjacent to the heel).
Further, in the land portion 15, a portion other than the first margin portion 11 and the second margin portion 12 is a second surface that is retracted radially inward from the margin portions 11 and 12.

  A leading edge (outer peripheral blade) is formed at least at the tip end in the axis O direction among the intersecting ridge line portions between the wall surface 2a facing the drill rotation direction T of the chip discharge groove 2 and the first margin portion 11. In the example of the present embodiment, the outer diameter of the blade portion of the drill body 1 is gradually reduced from the front end in the direction of the axis O toward the rear end side, and a back taper is given. Accordingly, the outer diameter of the leading edge is gradually reduced from the front end of the drill body 1 toward the rear end side. However, the present invention is not limited to this, and the back taper may not be provided to the blade portion of the drill body 1. That is, the outer peripheral blade of the drill body 1 may have a constant outer diameter along the axis O direction.

  In FIG. 1, the first margin portion 11 and the second margin portion 12 are the outermost diameter of the cutting edge 4 (the circle of the rotation locus formed by rotating the outer end in the radial direction of the cutting edge 4 around the axis O). Is located on a virtual cylindrical surface VC centered on an axis O having an outer diameter substantially equal to (diameter). The margin portions 11 and 12 gradually move to the opposite side of the drill rotation direction T from the front end in the direction of the axis O toward the rear end side as the chip discharge groove 2 extends spirally. Twists toward and extends spirally.

  In the drill 10 of this embodiment described above, the thinning cutting edge portion 9 of the cutting edge 4 is subjected to a honing process, and the thinning cutting edge portion 9 is a honing blade. The honing width of the thinning cutting edge portion 9 is such that the outer end in the radial direction of the thinning cutting edge portion 9 (that is, the thinning cutting edge portion 9 and the main cutting edge portion 13 located outside the thinning cutting edge portion 9 in the radial direction). Connection portion 16) and the maximum value at the radially inner end. Specifically, the position where the honing width is maximum in the thinning cutting edge portion 9 is the length X × (1/6) of the cutting length X of the thinning cutting edge portion 9 from the radially inner end to the outer end. And a position of length X × (1/3).

The portion of the thinning cutting edge portion 9 having the maximum honing width is located radially inward from the position of the length X × (1/3) from the radially inner end, so that the thinning cutting edge portion It is possible to improve the blade edge strength at the radially inner end portion 9 (near the axis O), and to prevent the chisel from being connected to the radially inner end portion.
That is, it is possible to secure a sufficient honing width at the radially inner end of the thinning cutting edge portion 9, which has a high cutting load and tends to lack cutting edge strength among the cutting edges 4, thereby increasing the rigidity of the drill tip and increasing the precision. Drilling can be performed stably.

  In addition, the portion of the thinning cutting edge portion 9 having the maximum honing width is located radially outward from the position of the length X × (1/6) from the radial inner end, so that the thinning cutting edge 9 It is possible to improve the manufacturability of the drill 10 (particularly the formability at the radially inner end (innermost end) of the thinning cutting edge portion 9) while reliably increasing the edge strength at the radially inner end of the portion 9. Further, since the honing width of the thinning cutting edge portion 9 is not the maximum at the radially inner end of the thinning cutting edge portion 9, the rigidity of the drill tip is increased in order to increase the honing width at the radially inner end. It is not reduced, and the rigidity of the drill tip can be secured to stably prevent the chisel from being lost.

  Further, since the maximum value of the honing width (maximum honing width) of the thinning cutting edge portion 9 is 1.5 times or more with reference to the honing width at the radially outer end of the thinning cutting edge portion 9, the thinning cutting edge 9 The blade edge strength at the radially inner end of the blade portion 9 can be reliably increased, and the above-described effects can be stably achieved.

  As described above, according to the present embodiment, the strength of the blade edge at the radially inner end portion of the thinning cutting edge portion 9 can be reliably increased, thereby preventing the chiple from being damaged and the like, and high-precision drilling can be performed for a long time. It is possible to carry out stably over a long time.

  In the present embodiment, the rake angle of the thinning cutting edge portion 9 is constant over the entire length of the thinning cutting edge portion 9. For this reason, as described above, the sharpness of the thinning cutting edge portion 9 can be increased uniformly over the entire length of the cutting edge while increasing the strength of the cutting edge of the thinning cutting edge portion 9.

  Moreover, in this embodiment, since the maximum honing width of the thinning cutting edge portion 9 is 2.5 times or less on the basis of the honing width at the radially outer end of the thinning cutting edge portion 9, the thinning cutting edge portion 9 It is possible to prevent the honing width from changing too much in the blade length region. As a result, it is possible to prevent a large cutting load from acting locally on the thinning cutting edge portion 9 during cutting (that is, the cutting load on the cutting edge can be substantially equalized over the entire length of the cutting edge), and the tip rigidity of the drill 10 is reduced. Secured. Further, the ease of manufacturing the thinning cutting edge portion 9 is also favorably maintained.

Moreover, in the example of this embodiment, the honing width | variety of the thinning cutting-blade part 9 is 50 micrometers or more and 100 micrometers or less.
If the honing width | variety of the thinning cutting edge part 9 shall be 50 micrometers or more like the said structure, the blade edge strength of the thinning cutting edge part 9 can be improved reliably.
Moreover, if the honing width | variety of the thinning cutting edge part 9 shall be 100 micrometers or less, the sharpness of the thinning cutting edge part 9 can be maintained favorable.

In the present embodiment, the drill 10 is a twist drill, and the first intersecting ridge line of the pair of intersecting ridge lines R is a front view of the drill body 1 viewed from the front end in the axis O direction toward the rear end side. An extension line L extending R1 toward the second intersecting ridgeline R2 coincides with the second intersecting ridgeline R2, or on the opposite side of the drill rotation direction T from the second intersecting ridgeline R2. Be placed.
For this reason, the ratio of the thinning surface 5 tends to increase with respect to the tip surface (tip flank surface) 3, and since the thinning surface 5 is formed large, the chip discharging property is excellent and the cutting resistance is reduced. In addition, a large space on the rake face (thinning wall surface 14) at the radially inner end of the thinning cutting edge 9 (a space for a chip pocket of the thinning cutting edge 9) can be secured, particularly in the vicinity of the chisel. It is possible to improve chip discharge by suppressing chip clogging. Thereby, the precision of drilling is stably improved.

Specifically, in the example of the present embodiment, of the pair of intersecting ridge lines R, an extension line L extending the first intersecting ridge line R1 toward the second intersecting ridge line R2 is more than the second intersecting ridge line R2. Is arranged on the opposite side to the drill rotation direction T, and the distance A along the circumferential direction between the extension line L and the second intersecting ridgeline R2 is 0.04 mm or less.
If the distance A along the circumferential direction between the extended line L of the first intersecting ridge line R1 and the second intersecting ridge line R2 is 0.04 mm or less as in the above configuration, the thinning is performed as described above. While increasing the area ratio of the surface 5 and improving the chip discharging property, it is possible to prevent the rigidity of the chisel from being reduced and to maintain the drill tip rigidity satisfactorily.

  In the present embodiment, the main cutting edge portion 13 of the cutting edge 4 is subjected to a honing process, and the main cutting edge portion 13 is also a honing blade. That is, since the cutting edge 4 is subjected to honing treatment over the entire cutting edge length, the cutting edge strength of the cutting edge 4 is increased over the entire cutting edge length. In addition, since the honing width of the main cutting edge portion 13 is constant over the entire length of the main cutting edge portion 13, the drill 10 can be easily manufactured.

Moreover, in this embodiment, since the recessed part 20 is formed in the radial direction inner end part of the thinning surface 5, there exists the following effect.
That is, in this case, chips generated by cutting the work material by the thinning cutting edge portion 9 are temporarily held in the concave portion 20 and discharged, whereby chip clogging in the vicinity of the chisel can be prevented. That is, the chip discharging property near the thinning cutting edge portion 9 is enhanced, and the accuracy of the drilling process can be improved.

  The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention, for example, as described below.

  In the above-described embodiment, the honing width of the main cutting edge portion 13 is constant over the entire blade length of the main cutting edge portion 13, but is not limited thereto. That is, the honing width of the main cutting edge portion 13 may be increased or decreased along the blade length direction of the main cutting edge portion 13.

  Moreover, although the above-mentioned embodiment gave and demonstrated the example in which the honing process was performed over the full blade length of the cutting blade 4, it is not limited to this. Of the cutting edges 4, at least the thinning cutting edge 9 may be a honing edge. Therefore, the main cutting edge portion 13 may not be a honing blade. Alternatively, a part or more of the blade length region of the main cutting edge portion 13 may be a honing blade.

  In the above-described embodiment, the thinning cutting edge portion 9 is a composite honing formed by combining chamfa honing and round honing. However, the present invention is not limited to this. The thinning cutting edge portion 9 may be chamfer honing or round honing other than composite honing.

  Moreover, although the drill 10 demonstrated by the above-mentioned embodiment is a two-blade twist drill, this invention is not limited to this. The drill 10 may be a drill having three or more blades.

  In addition, in the range which does not deviate from the meaning of this invention, you may combine each structure (component) demonstrated by the above-mentioned embodiment, a modification, and a remark etc., addition of a structure, omission, substitution, others It can be changed. Further, the present invention is not limited by the above-described embodiments, and is limited only by the scope of the claims.

  The drill of the present invention can increase the strength of the edge of the inner edge in the radial direction of the thinning cutting edge, thereby preventing chipping and the like and stably performing highly accurate drilling. Therefore, it has industrial applicability.

DESCRIPTION OF SYMBOLS 1 Drill main body 2 Chip discharge groove 2a Wall surface 3 Tip surface (tip flank)
4 Cutting edge 5 Thinning surface 9 Thinning cutting edge 10 Drill 13 Main cutting edge 16 Connection part (radial outer edge of the thinning cutting edge)
20 Concave portion A Distance L Extension line (virtual straight line)
O axis line R crossing ridgeline R1 first crossing ridgeline (one crossing ridgeline)
R2 Second intersection ridgeline (the other intersection ridgeline)
T Drill rotation direction

Claims (7)

A drill body that has an axial shape and is rotated in the drill rotation direction out of the circumferential direction around the axis;
On the outer periphery of the drill body, a chip discharge groove extending from the front end in the axial direction toward the rear end side,
A cutting edge formed on a cross ridge line portion between the wall surface of the chip discharge groove facing the drill rotation direction and the tip surface of the drill body;
A thinning surface formed between the tip surface and the chip discharge groove adjacent to the tip surface on the side opposite to the drill rotation direction;
Among the cutting edges, the thinning cutting edge portion located at least in the radially inner portion perpendicular to the axis is a honing blade,
The position where the honing width is maximum in the thinning cutting edge portion is
The cutting length of the thinning cutting edge is X, and is radially outside the position of length X × (1/6) from the radial inner end to the radial outer end of the thinning cutting edge, and , Radially inward from the position of length X × (1/3),
The drill whose maximum value of the honing width of the thinning cutting edge portion is 1.5 times or more with respect to the honing width at the radially outer end of the thinning cutting edge portion. The drill according to claim 1,
A drill in which the rake angle of the thinning cutting edge is constant over the entire length of the thinning cutting edge. The drill according to claim 1 or 2,
The drill whose maximum value of the honing width of the said thinning cutting edge part is 2.5 times or less with respect to the honing width in the radial direction outer end of the said thinning cutting edge part. The drill according to any one of claims 1 to 3,
The drill is a twist drill, and a pair of the tip surface and the thinning surface is formed on the drill body,
When the drill body is viewed from the front end to the rear end side in the axial direction,
The intersecting ridge line between the tip surface and the thinning surface is linear,
Of the pair of intersecting ridge lines, an extension line extending the first intersecting ridge line toward the second intersecting ridge line coincides with the second intersecting ridge line, or drills more than the second intersecting ridge line. A drill placed on the opposite side of the direction of rotation. The drill according to claim 4,
Of the pair of intersecting ridge lines, an extension line extending the first intersecting ridge line toward the second intersecting ridge line is disposed on the side opposite to the drill rotation direction with respect to the second intersecting ridge line,
The drill whose distance along the circumferential direction between the said extension line and the said 2nd intersection ridgeline is 0.04 mm or less. It is a drill as described in any one of Claims 1-5,
The cutting edge has a main cutting edge portion connected to a radially outer side of the thinning cutting edge portion,
The main cutting edge portion is a honing blade,
A drill in which the honing width of the main cutting edge is constant over the entire length of the main cutting edge. It is a drill as described in any one of Claims 1-6,
The drill in which the recessed part is formed in the radial direction inner end part of the said thinning surface.

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