JP2009083092A - Drill - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a drill capable of supplying a sufficient amount of clean cutting fluid, uniformly spreading the cutting fluid to a cutting edge of the drill and a peripheral side surface, avoiding a shortened lifetime by preventing the drill from wearing early, and preventing seizure of an inner wall surface of a processing hole and the peripheral side surface of the drill due to frictional heat, with an unlimited amount of being reground. <P>SOLUTION: A cutting fluid feeding hole extending from a rear end side to an edge side is drilled inside a drill body 10. On a peripheral side surface of a blade edge part 11, a land part 17 formed between chip discharging grooves 13A, 13B is provided with a cutting fluid guiding groove 30A extending from an edge of the blade edge part 11 to the rear end side in parallel with the tip discharging grooves 13A, 13B and having the cutting fluid feeding hole 36B opened thereon. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a drill used for drilling for forming a machining hole in a work material, and in particular, to form a work hole in a work material made of a difficult-to-cut material such as stainless steel. The present invention relates to a drill suitable for the above.

  Conventionally, a pair of chip discharge grooves extending toward the rear end side are formed on the outer peripheral side surface of the cutting edge portion, which is the tip side portion of the drill body rotated about the axis, and the pair of chip discharge grooves are forward in the drill rotation direction. There is known a so-called double-edged drill in which a pair of cutting blades are formed at a crossing ridge line portion between a wall surface facing the side and a tip flank surface of a blade edge portion. When machining with such a two-blade drill, the resistance during cutting is reduced, the wear progresses and the life of the cutting edge is extended, and the inner wall of the drilled hole and the drill are prevented from seizing due to frictional heat. Therefore, it is necessary to supply cutting fluid near the tip of the drill.

In the drill described in Patent Document 1, a cutting fluid supply hole is drilled from the rear end side of the drill body toward the tip, and a plurality of openings are formed with respect to one cutting blade. It is opened near the surface, and is configured to perform lubrication and cooling by discharging a cutting fluid from the opening. Further, in the drill described in Patent Document 2, the supply hole is opened not on the tip flank of the drill but on the inner wall surface of the chip discharge groove and the outer peripheral side surface of the tip of the drill. Lubrication and cooling can be performed between the inner wall and the inner wall.
JP 2005-1082 A Japanese National Patent Publication No. 11-508829

  By the way, when drilling a workpiece made of a metal material, the inner peripheral wall of the processing hole formed by the cutting blade contracts, so the outer peripheral side is tightened at the tip of the drill, and resistance and friction during cutting are large. This is particularly noticeable in the case of difficult-to-cut materials such as stainless steel. However, in the drill described in Patent Document 1, since the cutting fluid supply hole is opened only in the vicinity of the tip flank, the discharged cutting fluid wraps around the outer peripheral surface with fine chips, and the outer peripheral surface of the drill. There is a problem that wear due to biting occurs between the inner wall surface of the machined hole and the contracted hole.

  Moreover, in the drill of patent document 2, since the supply hole of the cutting fluid is branched on the inner wall surface of the chip discharge groove to form a plurality of openings, the cutting fluid is supplied to the supply hole from the rear end side. However, the cutting fluid is dispersed and discharged from a plurality of openings, and an effective amount of cutting oil may not be ensured. Also, depending on the state of the cutting fluid flow, the cutting fluid may concentrate in one of the openings, so the cutting fluid will not be discharged from the other openings, and the progress of drill wear will be partially accelerated. In addition to shortening the service life, the heat generated by friction cannot be removed, and when used for a long time, the drill and the processed hole may be seized.

  Furthermore, even when the opening of the supply hole is provided on the outer peripheral side surface of the drill, the discharge of the cutting fluid is localized and is difficult to spread over the entire outer peripheral side surface, so the outer peripheral side surface of the drill and the inner wall surface of the machining hole It was not possible to expect sufficient lubrication and cooling effects. Also, when re-polishing the drill, depending on the polishing amount, the branched portion of the supply hole appears on the polishing surface and the surface shape of the drill changes, so that the polishing amount is limited to avoid this There was a problem.

  In view of such circumstances, the present invention makes it possible to supply a sufficient amount of clean cutting fluid, and to distribute the cutting fluid evenly to the cutting blade and the outer peripheral surface of the drill. A drill that prevents premature wear and avoids shortening the service life, prevents seizure of the inner wall surface of the drilled hole and the outer peripheral surface of the drill due to frictional heat, and does not limit the amount of regrind. The purpose is to provide.

In order to solve the above problems, the present invention proposes the following means.
That is, in the drill according to the present invention, a chip discharge groove extending from the tip of the blade tip portion toward the rear end side is formed on the outer peripheral side surface of the blade tip portion which is the tip side portion of the drill body rotated about the axis, In the drill in which a cutting edge is formed at a crossing ridge line portion between a wall surface facing the front side in the drill rotation direction of the chip discharge groove and the tip flank surface of the cutting edge portion, the drill body has a tip side to a tip side. A cutting oil supply hole extending toward the edge is formed, and a land portion formed between the chip discharge grooves is formed on the outer peripheral side surface of the cutting edge portion from the front end to the rear end side of the cutting edge portion. A cutting oil guide groove extending in parallel with the chip discharge groove and having the cutting oil supply hole opened therein is provided.

  Therefore, in the drill of the present invention configured as described above, the cutting oil supply hole is opened in the cutting oil guide groove extending from the front end of the blade edge portion toward the rear end side, and the discharged cutting oil is Since it spreads along the cutting oil guide groove, it is possible to spread the clean cutting oil uniformly and with a sufficient amount of cutting oil over a wide range on the outer peripheral side surface of the cutting edge portion of the drill, particularly on the tip side. Furthermore, since the cutting oil guide groove extends in parallel with the chip discharge groove, the surface shape of the drill does not change even when re-polishing and the polishing amount is not limited.

  In the drill according to the present invention, the cutting oil guide groove includes a first cutting oil guide groove extending from the front end of the cutting edge portion toward the rear end side, and a rear in the first cutting oil guide groove. Even if it consists of a second cutting oil guide groove that opens to the end side, is narrower and deeper than the first cutting oil guide groove, and communicates with the cutting oil supply hole Good.

  According to the drill having such a feature, the cutting oil discharged from the cutting oil supply hole into the second cutting oil guide groove which is narrower and deeper than the first cutting oil guide groove, By spreading to the first cutting oil guide groove that is wide and shallow in groove depth, the cutting oil can be spread over a wider range, and the cutting oil should be supplied closer to the outer peripheral side of the cutting edge Therefore, it is possible to improve the lubrication effect and cooling effect of the cutting fluid.

  Further, in the drill according to the present invention, the land portion has an outer peripheral surface with an outer diameter substantially equal to the cutting edge and an axis centered on the axis line at an edge portion connected to a rear side in the drill rotation direction of the chip discharge groove. A margin portion having an arcuate cross section is formed, and an outer peripheral surface of the edge portion connected to the rear side in the drill rotation direction of the cutting oil guide groove has an outer diameter substantially equal to the cutting edge and is centered on the axis. A guide pad having an arcuate cross section is formed.

  The cutting fluid discharged from the opening at the tip flank of the cutting oil supply hole takes its heat in order to cool the cutting blade, and further mixes with the hot chips to increase the temperature. If such a mixture of cutting oil and chips wraps around the outer peripheral side surface of the cutting edge of the drill, both the lubrication effect and the cooling effect are reduced. In the drill according to the present invention, the outer peripheral side surface surrounds the cutting oil guide groove in a cross section perpendicular to the axis by the margin part and guide pad having an outer diameter substantially equal to the cutting edge, and the inner wall surface of the machining hole in contact with them. Since the cutting oil guide groove and the chip discharge groove are separated, the cutting oil mixed with the chip and having heat does not reach the outer peripheral side surface of the drill. Therefore, only the clean cutting fluid from the opening of the cutting oil supply hole in the cutting oil guide groove can be supplied to the outer peripheral side surface of the drill. Thereby, while reducing the friction of the margin part of the outer peripheral side surface of a drill, and the part which a guide pad and the inner wall face of a processing hole slidably contact, it can cool and can perform favorable cutting.

  Moreover, in the drill which concerns on this invention, the concave curved surface shape which becomes concave at the drill rotation direction front side may be sufficient as the wall surface which faces the drill rotation direction back side of the said cutting oil guide groove | channel. As a result, the intersecting ridge line portion composed of the wall surface facing the front side in the drill rotation direction of the cutting oil guide groove and the guide pad provided on the edge portion on the drill rotation direction side in contact with the cutting oil guide groove of the land portion is the drill. Since it becomes sharply sharp toward the rotation direction, the inner wall surface of the machining hole cut by the cutting blade is recut by this intersecting ridge line portion, and the machining accuracy can be improved.

  Furthermore, in the drill according to the present invention, the cutting edge portion is formed in a stepped shape whose outer diameter is made smaller through a step portion with respect to the rear end side than the distal end portion, It may be configured as a stepped drill in which a stepped blade is formed at a cross ridge line portion between the wall surface facing the front side in the drill rotation direction of the chip discharge groove and the stepped portion. By forming the guide groove so as to extend beyond the stepped portion from the tip of the cutting edge portion, the cutting fluid can be distributed to the stepped blade in the stepped portion.

  According to the drill of the present invention, it is possible to supply a sufficient amount of cutting fluid, particularly on the tip side of the cutting edge where the tightening force due to contraction of the machining hole acts, and to clean the cutting fluid with the cutting blade of the drill. Even if the work material is a difficult-to-cut material such as stainless steel, the drill is prevented from wearing out early and avoids shortening the life and friction. It is possible to prevent seizure of the inner wall surface of the processed hole and the outer peripheral side surface of the drill due to heat, and it is possible to perform re-polishing without being limited by the polishing amount.

  Hereinafter, a first embodiment of the drill of the present invention will be described in detail with reference to FIGS. 1 to 3. FIG. 1 is a side view showing a drill main body of a drill according to a first embodiment of the present invention, and FIG. 2 is a front end view of the drill main body of the drill according to the first embodiment of the present invention as viewed from the front end side. 3 is a cross-sectional view taken along the line AA of FIG.

  As shown in FIG. 1, the drill body 10 of the drill according to the first embodiment is formed in a substantially cylindrical shape centering on the axis O with a hard material such as cemented carbide, and the rear end side portion thereof is A shank portion (not shown) gripped by the rotating shaft of the machine tool is provided, and a tip end portion is a blade edge portion 11. A pair of chip discharge grooves 13 that twist to the rear side in the drill rotation direction T at a constant twist angle from the tip flank 12 toward the rear end side in the axis O direction are formed on the outer peripheral side surface of the cutting edge portion 11 with respect to the axis O. It is formed in a spiral shape so as to be symmetrical, and cutting edges 14 are respectively formed on the intersecting ridge line portions of the wall surface 13A facing the front side of the drill rotation direction T in the chip discharge grooves 13 and the tip flank 12.

  As shown in FIG. 2, the tip flank 12 of the blade tip 11 has a first flank 12 </ b> A in which the cutting edge 14 is formed at the ridge line portion on the front side in the drill rotation direction T when the chip discharge grooves 13 intersect with each other, The first flank 12 </ b> A has a multi-step surface composed of a second flank 12 </ b> B connected to the rear side of the drill rotation direction T of the first flank 12 </ b> A. In addition to this, a relief is given which increases in a multi-step manner toward the rear side in the drill rotation direction T. Further, the tip flank 12 is inclined toward the rear end side in the axis O direction from the inner peripheral side of the drill main body 10 toward the outer peripheral side of the drill main body 10, and the cutting edge 14 has a predetermined front end angle. It has come to be attached.

  Here, in the first embodiment, as shown in FIG. 2, the cutting edge 14 formed at the intersecting ridge line portion of the wall surface 13 </ b> A facing the front side of the drill rotation direction T of the chip discharge groove 13 and the tip flank 12. In addition, the outer peripheral side is a convex curved cutting edge portion 15 having a curved shape convex toward the front side of the drill rotation direction T, and the inner peripheral side of the drill body from the convex curved cutting edge portion 15 is the drill rotation direction T. A concave curved cutting edge portion 16 is formed which has a concave curved shape on the rear side and is continuously in contact with the convex curved cutting edge portion 15. Thereby, between these uneven curved cutting edge parts 15 and 16, the cutting edge 14 will exhibit S shape which curves gently seeing from the front end side of an axis O direction.

  Further, at the tip of the cutting edge portion 11, the intersection ridge line portion of the bottom surface of the chip discharge groove 13 and the wall surface 13B facing the rear side of the drill rotation direction T and the tip flank 12 (first flank 12A and second flank 12B). Is cut toward the inner side of the chip discharge groove 13 as it crosses the axis O toward the rear end side of the blade edge portion 11, thereby leading to the inner peripheral end side of the cutting blade 14 and reaching the land portion 17. A thinning portion 20 is formed so as to reach. Therefore, the inner peripheral end side of the cutting edge 14 is formed as a thinning cutting edge portion 21 which is formed at the intersecting ridge line portion between the thinning portion 20 and the first flank 12A and extends linearly toward the axis O. In the cutting blade 14, the portion where the thinning cutting edge portion 21 and the concave curved cutting edge portion 16 intersect with each other is a curve or straight line that protrudes forward in the drill rotation direction T when viewed from the front end side in the axis O direction. Connected smoothly.

  In the thinning portion 20 that intersects both wall surfaces 13A and 13B of the chip discharge groove 13 and extends toward the inner peripheral side of the drill body 10 and the front end side in the axis O direction, the both wall surfaces 13A and 13B of the chip discharge groove 13 are connected to each other. The flat first thinning surface extending along the axis O direction faces the front side of the drill rotation direction T and intersects the portion (groove bottom of the chip discharge groove 13) and continues to the thinning cutting edge portion 21. 22 Moreover, in the thinning part 20, the part which cross | intersects the wall surface 13B which faces the drill rotation direction T back side in the chip discharge groove 13 and continues to the 2nd flank 12B faces the drill rotation direction T back side, and becomes the land part 17. The flat second thinning surface 23 extends so as to reach the rear end side in the axis O direction as it extends toward the rear side in the drill rotation direction T.

  The thinning portion 20 has a valley shape in which the first thinning surface 22 and the second thinning surface 23 constituting the thinning portion 20 are crossed at an obtuse angle, and the intersection of the first thinning surface 22 and the second thinning surface 23 is formed. The part is directed from the connecting portion between both wall surfaces 13A, 13B of the chip discharge groove 13 (groove bottom of the chip discharge groove 13) toward the inner peripheral end of the cutting blade 14 (inner peripheral end of the thinning cutting blade part 21). That is, it extends so as to extend toward the axis O located at the center of the tip flank 12 and is inclined toward the tip side in the direction of the axis O as it goes toward the inner peripheral side of the drill body 10.

  The outer peripheral side surface of the blade edge portion 11 excluding the pair of chip discharge grooves 13, that is, the land portion 17, is shorter than the chip discharge groove 13 from the front end of the blade edge portion 11 toward the rear end side at a substantially central portion in the circumferential direction. Up to a predetermined position, the pair of cutting oil guide grooves 30 that twist to the rear side in the drill rotation direction T with a constant twist angle equal to the twist angle of the chip discharge groove 13 is symmetrical with respect to the axis O and the chips are discharged. It is formed in a spiral shape so as to extend in parallel with the groove 13. In addition, the groove width and groove depth of these cutting oil guide grooves 30 are sufficiently smaller than the chip discharge groove 13.

  Here, in the first embodiment, the wall surface 30A facing the front side of the drill rotation direction T of the cutting oil guide groove 30 is a convex curved surface that is convex toward the front side of the drill rotation direction T in a cross section orthogonal to the axis O. In addition, the wall surface 30B facing the rear side of the drill rotation direction T has a concave curved surface that is concave on the front side of the drill rotation direction T in the cross section orthogonal to the axis O, and the groove bottom of the cutting oil guide groove 30 is A concave curved surface that is smoothly connected to the wall surfaces 30A, 30B is formed, and the land portion 17 is divided into two in the circumferential direction by the cutting oil guide groove 30, and the first land portion 17A located on the front side in the drill rotation direction T. And the 2nd land part 17B located in the drill rotation direction T back side is formed.

  As shown in FIG. 2, the first land portion 17 </ b> A is formed on the edge of the first land portion 17 </ b> A on the drill rotation direction T side that contacts the chip discharge groove 13, and the chip discharge groove 13 has a front side in the drill rotation direction T. A margin portion 18A that intersects with the outer peripheral side ridge line portion of the wall surface 13A facing and has an outer peripheral surface that is substantially equal in diameter to the cutting edge 14 and has a cross-sectional arc shape about the axis O, and a drill rotation direction of the margin portion 18A The second back surface 18B is formed in a substantially arc shape centering on the axis O having an outer diameter one step smaller than the arc formed by the margin portion 18A.

  The second land portion 17B has a wall surface 30A facing the front side in the drill rotation direction T of the cutting oil guide groove 30 at the edge in the drill rotation direction T side of the second land portion 17B in contact with the cutting oil guide groove 30. A guide pad 31A having an outer diameter substantially equal to the cutting edge 14 and having an arcuate cross section centering on the axis O, intersecting with the outer peripheral ridge line portion, and a drill rotation direction T rear side of the guide pad 31A. A second picking surface 31B having a substantially arc shape centering on an axis O having an outer diameter that is one step smaller than the arc formed by the guide pad 31A is formed. Similar to the cutting oil guide groove 30, the guide pad 31A and the second picking surface 31B have a torsion angle equal to the chip discharge groove 30 from the portion intersecting the tip flank 12 toward the rear end side in the axis O direction. It is formed so as to be twisted in the drill rotation direction T rear side and in the same direction as the cutting oil guide groove 30 in the direction of the axis O of the cutting edge portion 11.

  And in the drill main body 10 between a pair of chip | tip discharge grooves 13 adjacent in the circumferential direction, it extends toward the front-end | tip from the rear-end side of the axis O direction, and the cross section orthogonal to the axis O makes a substantially circular shape. Four cutting oil supply holes 35 are formed so as to avoid the chip discharge groove 13 and to form a spiral shape corresponding to the twist of the chip discharge groove 13. Further, the cutting oil supply holes 35 are arranged on a straight line passing through the axis O so as to be symmetric with respect to the axis O in a cross section perpendicular to the axis O, and are spaced apart from the axis O by equal intervals. Yes.

  Of these four cutting oil supply holes 35, two cutting oil supply holes 35 </ b> A located inside the drill main body 10 extend over the entire length from the rear end of the drill main body 10 to the tip of the cutting edge portion 11. The flank oil hole 36A is formed so as to be opened on the second flank 12B. The remaining two cutting oil supply holes (not shown) located on the outer peripheral side of the drill main body 10 extend from the rear end of the drill main body 10 to a portion where the cutting oil guide groove 30 of the blade edge portion 11 is formed. The outer periphery side oil holes 36 </ b> B are respectively opened on the bottom side of the rear end of the cutting oil guide groove 30. Further, the cross-sectional area of the two cutting oil supply holes 35A located inside the drill body 10 is larger than the cross-sectional area of the two cutting oil supply holes (not shown) located on the outer peripheral side.

  The cutting oil supply groove 30 and the guide pad 31A are not formed on the rear end side of the tip end portion where the cutting oil guide groove 30 of the cutting edge portion 11 is formed. The cut surface 18B is formed so as to continue to the rear end (heel) of the land portion 17 in the drill rotation direction T.

  The drill according to the first embodiment configured as described above is fed toward the distal end side in the direction of the axis O while the drill body 10 is rotated in the direction T around the axis O. The work material is drilled, and chips generated by the cutting blade 14 are discharged toward the rear end side of the chip discharge groove 13 while being curled by both wall surfaces 13A and 13B of the chip discharge groove 13. By doing so, the drilling process is continued.

  At the time of drilling, the cutting oil 14 is discharged and supplied from the flank oil hole 36A to the second flank 12B in the cutting oil supply hole 35A, thereby lubricating and cooling the cutting edge 14 and the bottom of the machining hole. At the same time, the chips generated by the cutting blade 14 are pushed into the chip discharge groove 13 and discharged. Further, the cutting fluid is also discharged from the outer peripheral side oil hole 36B formed in the cutting oil guide groove 30, and lubrication and cooling are performed on the outer peripheral side surface (particularly, the land portion 17) of the cutting edge portion 11 of the drill.

  In the drill according to the present embodiment, the plurality of cutting oil supply holes 35 are provided independently so as to extend from the rear end side to the front end side of the drill body 10, and further, these cutting oil supply Each of the holes 35 is opened at one place to form a flank oil hole 36A and an outer peripheral oil hole 36B. Therefore, the cutting fluid supplied to the respective cutting oil supply holes 35 from the rear end side is discharged from the oil holes 36 (36A, 36B), which are one opening, respectively. A sufficient amount of cutting oil can be secured at 36B.

  Also, a cutting oil supply hole (not shown) that opens in the outer peripheral side surface of the cutting edge portion 11 in the cutting oil supply hole 35 opens into a cutting oil guide groove 30 that extends from the front end toward the rear end side, and the outer peripheral oil Since the hole 36B is formed and the cutting fluid discharged from the outer peripheral side oil hole 36B spreads along the cutting oil guide groove 30, the drill body 10 in which the cutting oil guide groove 30 is formed in the direction of the axis O. The cutting fluid can be spread evenly over a wide range of the outer peripheral side surface of the blade edge portion 11.

  Further, at the time of cutting, the cutting fluid discharged from the flank oil hole 36A, which is an opening in the tip flank 12 of the cutting oil supply hole 35A, takes its heat to cool the cutting blade, and further has heat. The temperature rises due to mixing with chips. If such a mixture of cutting fluid and chips wraps around the outer peripheral side surface of the cutting edge portion 11 of the drill, the lubricating effect is lowered and the cooling effect is also lowered.

  In the drill according to the present embodiment, the cutting oil guide groove 30 is surrounded in a cross section perpendicular to the axis O by the margin portion 18A having an outer peripheral surface substantially equal to the cutting edge 14, the guide pad 31A, and the wall surface of the machining hole. Thus, the cutting oil guide groove 30 and the chip discharge groove 13 are separated. Therefore, the cutting fluid mixed with chips and having heat does not reach the outer peripheral side surface of the drill body 10, and the outer peripheral side surface of the cutting edge portion 11 is cleaned from the outer peripheral side oil hole 36 </ b> B located in the cutting oil guide groove 30. Only a cutting fluid can be supplied. Thereby, since cutting fluid mixed with chips does not reach the outer peripheral side surface and the heat does not reach, the friction of the portion where the margin portion 18A or the guide pad 31A and the wall surface of the processing hole are in sliding contact is reduced and cooled. And good cutting can be performed.

  Further, the two flank oil holes 36A are obtained by opening two cutting oil supply holes 35A provided independently of each other, and there is no branched portion in the cutting oil supply holes 35A. Since the guide groove 30 is also parallel to the chip discharge groove 13 and the cutting edge portion 11 is always in the same shape in the cross section perpendicular to the axis O, the surface shape of the tip flank 12 of the drill does not change even when re-polished. The amount of polishing is not limited.

  Next, a second embodiment of the drill according to the present invention will be described. FIG. 4 is a side view showing a drill body of a drill according to the second embodiment of the present invention, and FIG. 5 is a front end view of the drill body of the drill according to the second embodiment of the present invention as viewed from the front end side. 6 is an AA cross-sectional view in FIG. 4, and FIG. 7 is a BB cross-sectional view in FIG. 4 to 7, the same components as those in FIGS. 1 to 3 are denoted by the same reference numerals, and detailed description thereof is omitted. The drill of this embodiment is different from that of the first embodiment in that the cutting oil guide groove 30 includes a first cutting oil guide groove 40 and a second cutting oil guide groove 41, and the other configurations are the same. It has become.

  In the second embodiment, on the outer peripheral side surface of the blade edge portion 11 excluding the pair of chip discharge grooves 13, chips are cut from the tip of the blade edge portion 11 toward the rear end side to a predetermined position shorter than the chip discharge groove 13. A pair of first cutting oil guide grooves 40 twisted rearward in the drill rotation direction T with a constant twist angle equal to the twist angle of the discharge groove 13 are symmetric with respect to the axis O and formed in the chip discharge groove 13. On the other hand, it is formed in a spiral shape so as to extend in parallel. In addition, the groove width of these first cutting oil guide grooves 40 is formed so as to extend from the margin portion 18A to the guide pad 31A in the cross section perpendicular to the axis O, and the groove depth is the margin portion. 18A and the guide pad 31A are shallower than the arc formed by one step toward the inside, and are formed to have the same depth as the second picking surface 31B.

  On the other hand, at the predetermined position at the rear end of the first cutting oil guide groove 40, the first cutting oil guide groove 40 is rounded up to the outer peripheral side and has an outer diameter equal to that of the margin portion 18A and the guide pad 31A. Then, the oil spill prevention land 42 having an arcuate cross section with the axis O continuing to the margin portion 18A and the guide pad 31A as a center is connected. The oil spill prevention land 42 is narrowed in the circumferential width from the margin portion 18A toward the rear end side, and is connected to the margin portion 18A immediately on the rear end side of the predetermined position. On the end side, only the margin portion 18A and the second picking surface 31B are formed on the outer periphery of the land portion 17.

  Further, as shown in FIG. 4, the rear end portion in the first cutting oil guide groove 40 extends in parallel with the first cutting oil guide groove 40, and more than the first cutting oil guide groove 40. A second cutting oil guide groove 41 having a narrow width and a deep groove depth is provided, and an outer peripheral oil hole 36 </ b> B is opened in the second cutting oil guide groove 41.

  The second cutting oil guide groove 41 is formed so as to extend only to the rear end side of the first cutting oil guide groove 40, and the cutting edge portion like the cutting oil guide groove 30 of the first embodiment. 11 The tip flank 12 is not reached, and the tip side is rounded up to the bottom surface of the first cutting oil guide groove 40. Therefore, the cutting oil supply hole 35 </ b> B when the material of the drill body 10 is formed is left on the outer peripheral side in the land portion 17 of the cutting edge portion 11 at the distal end side of the second cutting oil guide groove 41. The cutting oil supply hole 35B is opened in the tip flank 12 to form a hole 36C that does not discharge the cutting oil.

  According to the drill of the second embodiment configured as described above, the cutting fluid discharged into the second cutting oil guide groove 41 that is narrower and deeper than the first cutting oil guide groove 40, By extending to the first cutting oil guide groove 40 which is wider and shallower than this, the cutting oil can be spread over a wider range, and the cutting is performed closer to the outer peripheral side surface of the cutting edge portion 11. Since the oil agent can be supplied, it is possible to effectively obtain the lubrication effect and the cooling effect by the cutting oil agent.

  Further, an oil outflow prevention land 42 is formed on the rear end side of the first cutting oil guide groove 40, and the cutting oil does not flow out to the rear end side, so that the cutting discharged from the outer peripheral side oil hole 36B is performed. An oil agent can be reliably supplied to the front-end | tip side of the blade edge | tip part 11. FIG. Further, since only the margin portion 18A and the second picking surface 31B are formed on the outer periphery of the land portion 17 on the rear end side from the oil spill prevention land 42, the frictional resistance with the inner periphery of the machining hole is reduced to rotate the drill. The driving force can be reduced.

  Next, a third embodiment of the drill according to the present invention will be described. FIG. 8 is a front end view of the drill body of the drill according to the third embodiment as viewed from the front end side. 8, the same components as those in FIG. 2 are denoted by the same reference numerals, and detailed description thereof is omitted. The drill of this embodiment is different from the first embodiment in that the wall surface 30C facing the front side of the drill rotation direction T of the cutting oil guide groove 30 is a concave curved surface that is concave on the rear side of the drill rotation direction T. Others have the same configuration.

  As a result, the wall surface 30C facing the front side of the drill rotation direction T of the cutting oil guide groove 30 and the intersecting ridge line portion 30D with the guide pad intersect each other at an acute angle, and become sharply sharp in the drill rotation T direction. The wall surface of the processed hole cut by the cutting edge by the intersecting ridge line portion 30D is recut, and the processing accuracy can be improved. In particular, since the intersecting ridge line portion 30D extends from the outer periphery of the front end flank 12 on which the cutting edge 14 is formed to the rear end side, the portion where the inner peripheral wall of the processing hole is contracted can be recut. The processing accuracy can be improved.

  Further, since the wall surface 30C facing the front side of the drill rotation direction T has a concave curved surface shape that is concave toward the rear side of the drill rotation direction T, it becomes easier to hold the cutting fluid in the cutting oil guide groove 30, and the cutting oil Scattering of the cutting fluid until the guide groove 30 enters the machining hole can be suppressed.

  Note that the surface 40C facing the front of the drill rotation direction T of the first cutting oil guide groove 40 in the second embodiment shown in FIG. 5 has a concave curved surface that is concave toward the rear side of the drill rotation direction T. There may be. Even in this case, it is possible to improve the machining accuracy and suppress the scattering of the cutting fluid.

  Furthermore, a fourth embodiment of the drill according to the present invention will be described. FIG. 9 is a side view showing a drill body of a drill according to the fourth embodiment of the present invention, and FIG. 10 is a front end view of the drill body of the drill according to the fourth embodiment of the present invention as viewed from the front side. 11 is a side view of the drill body of the drill according to the fourth embodiment of the present invention as viewed from the direction of the arrow L in FIG. In the fourth embodiment, the cutting edge portion 11 which is the distal end portion of the drill body 10 has an outer diameter that is one step smaller than the rear end portion 11B of the distal end portion 11A through the step portion 11C. It is formed in the shape of the step which was made, and it is set as the structure of what is called a step drill.

  That is, in the tip portion 11A, the outer diameter around the axis O of the margin portion 18A from the outer peripheral end of the cutting edge 14 is made one step smaller than the outer diameter around the axis of the margin portion 18A in the rear end portion 11B. In the step portion 11C, which changes from the tip portion 11A having a small outer diameter to the rear end portion 11B having a large outer diameter, the cross ridge line portion with the wall surface 13A facing the front side of the drill rotation direction T of the chip discharge groove 13 is on the rear end side. The outer diameter is gradually increased as it goes, and the stepped blade 50 is formed at the intersecting ridge portion. Note that the outer peripheral surface of the stepped portion 11C has a concave curved surface shape that is slightly recessed toward the inner peripheral side in the cross section along the axis O, whereby the stepped blade 50 also has a slightly concave curved shape. Escape is given to the outer peripheral surface serving as the flank of the attached blade 50 toward the rear side in the drill rotation direction T and the rear end side in the axis O direction.

  Further, the cutting oil guide groove 30 extending from the front end of the blade edge portion 11 toward the rear end side has a torsion angle equal to that of the chip discharge groove 13 from the front end flank 12 of the front end portion 11A which is the front end of the blade edge portion 11. It extends to the rear end side so as to be parallel to the chip discharge groove 13, extends beyond the step portion 11C to reach the front end side of the rear end portion 11B, and the cutting oil guide groove 30 is provided with a step. An oil hole 36 (outer peripheral oil hole 36B) is formed by opening an outer peripheral cutting oil supply hole at a portion intersecting with the portion 11C.

  In the fourth embodiment, the cutting oil guide groove 30 is formed in the first cutting oil guide groove 40 having a wide width and a shallow groove depth as in the second embodiment. A second cutting oil guide groove 41 that is narrower and deeper than the groove 40 is formed, and the outer peripheral oil hole 36B is opened in the second cutting oil guide groove 41. However, unlike the second embodiment, the second cutting oil guide groove 41 in the fourth embodiment is formed to reach the tip flank 12 together with the first cutting oil guide groove 40.

  Further, in the fourth embodiment, only the margin portion 18A and the second face 18B are formed on the outer periphery of the land portion 17 in the tip portion 11A and the rear end portion 11B of the cutting edge portion 11, and the cutting oil The guide groove 30 is formed so as to be recessed from the second picking surface 18B toward the inner peripheral side. Further, the cross-sectional shape perpendicular to the axis O is also substantially V-shaped or U-shaped so that the first cutting oil guide groove 40 is narrower and deeper than the first cutting oil guide groove 40 in the second embodiment. The second cutting oil guide groove 41 extends along the groove bottom of the first cutting oil guide groove 40 and has a sector shape in which the cross section perpendicular to the axis O is slightly larger in arc than the semicircle. As shown in FIG. 10, the radius is made larger than the radius of the flank oil hole 36A. The flank oil hole 36 and the first and second cutting oil guide grooves 40 and 41 of the cutting oil guide groove 30 are thinned with the second flank 12B of the tip flank 12 in the fourth embodiment. An opening is formed on the intersecting ridge line with the second thinning surface 23 of the portion 20.

  In the drill according to the fourth embodiment configured as described above, the stepped blade 50 is formed in the step portion 11C having an outer diameter that increases from the front end portion 11A to the rear end portion 11B of the blade tip portion 11 as described above. Therefore, if the cutting edge portion 11 is cut into the work material up to the stepped blade 50, the opening portion of the hole having an inner diameter equal to the outer diameter of the distal end portion 11A can be formed into a tapered shape. If even the end portion 11B is cut into the work material, a stepped hole in which a large diameter hole is formed through a step on the opening side of the small diameter hole can be formed.

  In the drill according to the fourth embodiment, the cutting oil guide groove 30 extends beyond the stepped portion 11C to reach the rear end portion 11B. The cutting fluid that reaches only the cutting edge 14 can be reliably distributed to the stepped blade 50 formed in the stepped portion 11C, and the cutting resistance by the stepped blade 50 is reduced and seizure is prevented. Is possible.

  As mentioned above, although embodiment in this invention was explained in full detail with reference to drawings, the concrete structure is not restricted to this embodiment, The design change of the range which does not deviate from the meaning of this invention is also included. For example, in the embodiment described above, four cutting oil supply holes 35 are provided, but five or more cutting oil supply holes are provided unless the strength and rigidity of the drill body 10 are inadvertently impaired. It may be. In the first to fourth embodiments, a so-called two-blade drill in which a pair of cutting blades 14 are formed is described. Instead, for example, a single-blade drill or a three-blade drill is used. The above drill may be used.

  Furthermore, although the so-called twist drill in which the chip discharge groove 13 is twisted to the rear side in the drill rotation direction T has been described, the present invention is not limited to this. For example, the chip discharge groove 13 is linear from the front end of the blade edge portion 11 to the rear end side. It may be a straight groove type drill extending in a straight line. Further, the shape of the cutting oil guide groove 30 of the fourth embodiment may be applied to the first to third embodiments, and conversely, the cutting edge portion 11 in the first to third embodiments is replaced with a stepped portion. 11C may be formed.

It is a side view which shows the drill main body of the drill which is 1st embodiment of this invention. It is the front end view which looked at the drill main body of the drill which is 1st embodiment of this invention from the front end side. It is AA sectional drawing of FIG. It is a side view which shows the drill main body of the drill which is 2nd embodiment of this invention. It is the front end view which looked at the drill main body of the drill which is 2nd embodiment of this invention from the front end side. It is AA sectional drawing of FIG. It is BB sectional drawing of FIG. It is the front end view which looked at the drill main body of the drill which is 3rd embodiment of this invention from the front end side. It is a side view which shows the drill main body of the drill which is 4th embodiment of this invention. It is the front end view which looked at the drill main body of the drill which is 4th embodiment of this invention from the front end side. It is a side view of the arrow L direction view in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Drill main body 11 Cutting edge part 11A Tip part of blade edge part 11B Rear edge part of cutting edge part 11C Step part 12 Tip clearance surface 13 Chip discharge groove 13A Wall faced to the front side in the drill rotation direction of chip discharge groove 14 Cutting edge 17 Land part 18A Margin portion 30 Cutting oil guide groove 30C Wall surface of cutting oil guide groove facing forward in the direction of drill rotation 31A Guide pad 35 Cutting oil supply hole 36A Flank oil hole 36B Outer oil hole 36C Flank oil hole 40 First cutting oil Guide groove 41 Second cutting oil guide groove 50 Stepped blade O Axis T Drill rotation direction

Claims (5)

A chip discharge groove extending from the front end of the blade tip portion toward the rear end side is formed on the outer peripheral side surface of the blade tip portion, which is the tip side portion of the drill body rotated about the axis, and the chip discharge groove is forward in the drill rotation direction. In the drill in which the cutting edge is formed at the intersecting ridge line part of the wall surface facing the side and the tip flank of the cutting edge part,
In the drill body, a cutting oil supply hole extending from the rear end side toward the front end side is drilled, and
On the outer peripheral side surface of the blade edge portion, a land portion formed between the chip discharge grooves extends in parallel to the chip discharge groove from the front end to the rear end side of the blade edge portion, and the cutting oil supply A drill characterized in that a cutting oil guide groove having a hole is provided. The cutting oil guide groove is
A first cutting oil guide groove extending from the front end of the blade edge portion toward the rear end side;
The second cutting that opens to the rear end side in the first cutting oil guide groove, is narrower and deeper than the first cutting oil guide groove, and communicates with the cutting oil supply hole The drill according to claim 1, comprising an oil guide groove. In the land portion, a margin portion having an outer peripheral surface substantially equal to the cutting edge and having an arcuate cross section around the axis is formed at an edge portion connected to the rear side in the drill rotation direction of the chip discharge groove. And
A guide pad having an outer peripheral surface substantially equal to the cutting edge and having a cross-sectional arc shape centering on the axis is formed at an edge portion of the cutting oil guide groove that is connected to the rear side in the drill rotation direction. The drill according to claim 1 or 2, characterized by the above.   The drill according to any one of claims 1 to 3, wherein a wall surface of the cutting oil guide groove facing the front side in the drill rotation direction has a concave curved surface that is concave on the rear side in the drill rotation direction. The cutting edge portion is formed in a stepped shape having an outer diameter reduced through a step portion with respect to the rear end side with respect to the rear end side with respect to the front end portion, and the front side in the drill rotation direction of the chip discharge groove A stepped blade is formed at the crossing ridge line part of the wall surface facing the step and the step part,
5. The drill according to claim 1, wherein the cutting oil guide groove extends beyond the stepped portion from a tip of the cutting edge portion. 6.

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