JP6251358B1 - Boring tools - Google Patents

Abstract

A boring tool capable of preventing undesired movement of a cutting edge tip is provided. A boring tool according to the present invention includes a tool main body (11) having a through hole (14), a head provided with a cutting edge tip, and a cartridge main body having a leg (23) passed through the through hole. (21) has a cylindrical portion (32) and a flange (33), a scale is provided on the flange, an internal thread (23f) is formed on the inner periphery of the cylindrical portion, and a leg portion protruding from the through hole A dial ring (31) that is screwed to the tip portion and a female screw hole that is screwed to a male screw (32f) formed on the outer periphery of the cylindrical portion, and a locked portion (36, 37), a lock flange (38) which is disposed between the locked portion and the flange and is fixed to the tool main body and abuts against the locked portion; And an elastic member (42) for biasing et away direction. [Selection] Figure 3

Description

  The present invention relates to a boring tool such as a boring bar for boring and cutting a workpiece.

  As a boring tool, the one described in Japanese Patent No. 36399939 (Patent Document 1) has been known. The boring tool described in Patent Document 1 includes a tool main body 111, a cartridge main body 121, a dial ring 131, a preloading nut 136, a lock flange 138, and a wave spring 142 as shown in FIG. The cartridge main body 121 has a leg portion 123, the leg portion 123 of the cartridge main body 121 is passed through the through hole 114 of the tool main body 111, and the head portion 122 of the cartridge main body 121 protrudes from the through hole 114 of the tool main body 111 to one side. A cutting edge tip 141 is provided. A male screw 123 f is formed on the outer periphery of the leg portion 123 of the cartridge main body 121 and is screwed into the dial ring 131. The dial ring 131 is engraved with a scale (not shown) at intervals in the circumferential direction. When the dial ring 131 is rotated, the cartridge main body 121 slides through the through hole 114 of the tool main body 111 according to the screw feed amount of the male screw 123f. Thereby, the protrusion amount of the cutting edge tip (distance from the center axis O of the tool body 111) is finely adjusted.

Japanese Patent No. 36399939

  However, the present inventor has found that there is a point to be further improved in the conventional boring tool. That is, as shown by an arrow in FIG. 16, an external force F may act on the cutting edge tip 141 from the workpiece. Since the direction of the external force F is parallel to the leg portion 123 of the cartridge main body 121, the wave spring 142 is pressed. Therefore, the external force F becomes excessive depending on the material of the workpiece and the cutting conditions, the wave spring 142 is compressed and deformed, and the cutting edge tip 141 may move in the direction indicated by the arrow F in FIG. . Then, the workpiece cannot be finished with the set boring diameter.

  Therefore, it is conceivable to increase the spring constant of the wave spring 142 and to make the wave spring 142 difficult to compress and deform. However, if the spring constant of the wave spring 142 is increased, the dial ring 131 is difficult to rotate this time, and it becomes difficult to finely adjust the protruding amount of the cutting edge tip.

  In view of the above circumstances, an object of the present invention is to prevent undesired movement of a cutting edge tip without sacrificing adjustment work of the cutting edge tip. It is another object of the present invention to enable the operator to easily rotate the dial ring with a small torque and to facilitate the adjustment work of the cutting edge tip.

  For this purpose, a boring tool according to the present invention includes a tool body having a through hole, a cartridge body having a head portion provided with a cutting edge tip and a leg portion passed through the through hole, a cylindrical portion, and the cylindrical portion. A dial ring that has a flange protruding in the outer diameter direction, a female thread is formed on the inner periphery of the cylindrical part, and is screwed to the tip of the leg part protruding from the through hole, and a male screw formed on the outer periphery of the cylindrical part Having a female screw hole to be screwed to the lock ring, and a locked portion disposed between the flange of the dial ring and the tool body, and disposed between the locked portion and the flange of the dial ring and fixed to the tool body. A lock flange that abuts against the flange, and is interposed between the lock flange and the flange of the dial ring to bias the dial ring flange away from the lock flange And a sexual member.

  According to the present invention, with respect to the through hole of the tool main body, the lock nut attached and fixed to the cartridge main body is disposed on the side close to the through hole of the tool main body. A lock flange fixed to the tool body is disposed on the far side from the through hole of the tool body. Since the lock nut comes into contact with the lock flange, even if an excessive external force acts on the cutting edge tip from the workpiece and tries to move the cartridge body along the through hole, the external force is received by the lock flange, and the cartridge The body does not move. Therefore, undesired movement of the cutting edge tip can be prevented.

  Moreover, according to this invention, the flange of a dial ring is arrange | positioned further in the side far from the through-hole of a tool main body regarding the through-hole of a tool main body. And since an elastic member is interposed between the flange of a lock flange and a dial ring, it is not pressed by the excessive external force given to a cutting-blade chip | tip from a workpiece | work. Therefore, the elastic coefficient of the elastic member may be small, the operator can rotate the dial ring with a small torque, and the adjustment work of the cutting edge tip becomes easy.

  The elastic member is not particularly limited, for example, a wave spring or a disc spring. Preferably, the dial ring and the lock flange are provided with means for visually recognizing the rotation angle of the dial ring. As such means, for example, a scale and a mark are attached to the dial ring and the lock flange, respectively. The shape of the lock flange is not particularly limited, but is a plate member having a central hole through which the cylindrical portion of the dial ring passes, and is fixedly attached to the tool body by, for example, a countersunk screw. Preferably, the lock flange may be formed with a recess for accommodating the elastic member, so that the lock flange can be brought close to the flange of the dial ring.

  The locked portion may be one member or a plurality of members, but is not elastically deformed in the extending direction of the leg portion and the through hole. As one embodiment of the present invention, the locked portion includes two lock nuts. According to this embodiment, the lock nut can be prevented from loosening by tightening the two lock nuts so as to press each other. The to-be-locked part should just contain at least 2 lock nuts. As another embodiment, only one lock nut may be screwed into the cylindrical portion of the dial ring.

  As another embodiment of the present invention, the locked portion includes one lock nut and an annular tongue washer passed through the cylindrical portion. According to such an embodiment, the tongue formed on a part of the washer in the circumferential direction can regulate the rotation of the tongue-mounted washer and / or can regulate the displacement of the tongue-mounted washer. Then, the dial ring can be allowed to rotate while holding the dial ring incapable of relative displacement when viewed from the tool body, and the cartridge body can be moved back and forth along the through hole by the rotation of the dial ring. Preferably, a tongue washer is interposed between the lock nut and the lock flange. Alternatively, as another embodiment, the locked portion may be a combination of a lock nut and a simple plain washer.

  Thus, according to the present invention, the cutting edge tip does not move even if an external force parallel to the extending direction of the through hole acts excessively on the cutting edge tip from the workpiece. Further, the elastic force of the elastic member can be reduced, and the operator can easily rotate the dial ring with a small torque. Therefore, the position of the cutting edge tip can be easily finely adjusted.

It is a side view which shows the boring head part of the tool for boring which becomes 1st Embodiment of this invention. It is a cross-sectional view which shows the boring head part of the embodiment. It is sectional drawing which expands and shows the dial ring of the embodiment. It is a perspective view which takes out a washer from the embodiment and shows. It is a side view which expands and shows the dial ring of the embodiment. It is a side view which shows the same embodiment. It is an exploded view which shows the tool holder and tool main body of FIG. It is a side view which shows the tool for boring which becomes 2nd Embodiment of this invention. It is an exploded view which shows the tool holder of FIG. 8, an adapter, and a tool main body. It is a side view which shows the tool for boring which becomes 3rd Embodiment of this invention. It is an exploded view which shows the tool holder of FIG. 10, an adapter, and a tool main body. It is a side view which shows the tool for boring which becomes 4th Embodiment of this invention. It is an exploded view which shows the tool holder of FIG. 12, an adapter, and a tool main body. It is a partial side view which shows the tool for boring which becomes 5th Embodiment of this invention. It is a cross-sectional view which shows the tool main body of FIG. It is sectional drawing which expands and shows the dial ring provided in the conventional tool for boring.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a side view showing a boring head portion of a boring tool according to a first embodiment of the present invention, and a tip of the boring tool at a cutting plane including a central axis (hereinafter referred to as axis O) of the boring tool. The side is cut to represent the cross section. The boring tool 10 includes a tool body 11, a tool holder 19, a cartridge body 21, a dial ring 31, and a cutting edge tip 41 as main components. The tool body 11 has a cylindrical shape extending along the axis O and has a coupling portion 12 at the rear end. The coupling portion 12 includes a joining surface 12b that is a plane perpendicular to the axis O and is oriented in the rear end direction, and a joining shaft portion 12c that protrudes from the center of the joining surface 12b. The tool main body 11 is mounted on the tool holder 19 when the coupling shaft portion 12 c is received by the tool holder 19 indicated by the phantom line and the joining surface 12 b comes into contact with the joining surface 19 c that becomes the tip surface of the tool holder 19. The tool holder 19 is chucked on a main shaft (not shown) on the rear end side. Thereby, the boring tool 10 rotates integrally. Since the tool body 11 occupies the tip of the boring tool 10, it is also called a head body. The tool body 11, the cartridge body 21, and the dial ring 31 are also referred to as a boring head portion. A tip pocket 13, a through hole 14, and a notch 15 are formed at the tip of the tool body 11.

  FIG. 2 is a cross-sectional view showing the embodiment, and shows a state in which the boring tool 10 is cut on a flat surface orthogonal to the axis O and the cut surface is viewed in the direction of the axis O. The chip pocket 13 and the notch 15 are provided on the outer periphery of the tool main body 11 and are spaced apart in the diameter direction. The through hole 14 is a round hole that extends straight from the chip pocket 13 to the notch 15 in the diameter direction of the tool body 11. The axis C of the through hole 14 is orthogonal to the axis O of the tool body 11. A concave portion 16 is formed at a connection portion between the through hole 14 and the notch portion 15. The recess 16 is a space smaller than the notch 15, but is larger than the diameter of the through hole 14.

  The cartridge body 21 is passed through the through hole 14. The cartridge main body 21 has a block-shaped head portion 22, a columnar leg portion 23, and a bolt 24 that connects and fixes them. The head portion 22 is formed with a concave portion 22b, a convex portion 22c, and a round hole 22d extending from the concave portion 22b to the convex portion 22c. A recess 23 c is formed at one end of the leg 23. The leg portion 23 has a female screw hole 23m extending from the recess 23c to the center of the leg portion 23. When the convex portion 22c of the head portion 22 is fitted into the concave portion 23c of the leg portion 23, the round hole 22d coincides with the female screw hole 23m. When the bolt 24 is inserted into the recess 22b, only the shaft portion of the bolt 24 is passed through the round hole 22d having a smaller diameter than the recess 22b, and the head of the bolt 24 is locked into the recess 22b. The shaft portion of the bolt 24 is screwed into the female screw hole 23m, whereby the head portion 22 and the leg portion 23 are connected and fixed.

  The head 22 of the cartridge body 21 is received in the chip pocket 13 of the tool body 11. The leg portion 23 of the cartridge body 21 is passed through the through hole 14 of the tool body 11 and protrudes into the notch portion 15. A male screw 23 f is formed on the outer periphery of the distal end portion of the leg portion 23. However, the outer peripheral surface from the base of the leg portion 23 (the connection portion with the head portion 22) to the intermediate region is formed smoothly.

  The cartridge body 21 extends along the axis C of the through hole 14. The axis C corresponds to the diameter of the tool body 11. In the following description, the direction from the notch 15 (leg part 23) to the tip pocket 13 (head 22) is also referred to as one of the axis C directions, and conversely from the tip pocket 13 (head 22) to the notch 15 (leg part). 23) is also referred to as the other axis C direction. The outer peripheral surface of the leg portion 23 and the inner peripheral surface of the through hole 14 are formed smoothly, and the cartridge body 21 can freely slide in the direction of the axis C of the through hole 14. Is prevented from moving in the other direction of the axis C.

  The chip pocket 13 has a flat surface 13 g that is parallel to the axis C and is oriented in the circumferential direction of the axis O. The head portion 22 of the cartridge body 21 has a flat side surface 22g that comes into contact with the flat surface 13g. The contact between the flat surface 13g and the side surface 22g does not hinder the sliding of the cartridge body 21. The flat surface 13g receives the reaction force that the cutting edge tip 41 receives from the workpiece when the boring tool 10 rotates about the axis O to cut the workpiece in a boring manner.

  On the surface of the leg portion 23, a belt-like flat surface 23g extending in the direction of the axis C is formed. The tool body 11 is formed with a female screw hole 11 m extending from the outer peripheral surface of the tool body 11 to the through hole 14. The female screw hole 11m is connected to one end of the through hole in the direction of the axis C and extends at right angles to the axis C. A set screw 43 is screwed into the female screw hole 11m. The tip of the set screw 43 is formed on a flat surface orthogonal to the extending direction of the set screw 43. A polygonal hole for engaging with a screwdriver is formed at the rear end of the set screw 43. By tightening the set screw 43 using a screwdriver, the tip of the set screw 43 presses the flat surface 23g, and the cartridge body 21 is fixed so as not to slide.

  FIG. 3 is an enlarged cross-sectional view showing the tip of the cartridge body 21 and the dial ring 31 shown in FIG. FIG. 5 is a side view of the same embodiment, showing the dial ring 31 in an enlarged manner, as viewed from the leg side (the other in the direction of the axis C) of the cartridge body 21, that is, as viewed in a direction perpendicular to the axis O. Represents. The dial ring 31 has a cylindrical portion 32 and a flange 33. A female screw is formed on the inner peripheral surface of the cylindrical portion 32 and is screwed into the male screw 23 f of the cartridge body 21. The flange 33 of the dial ring 31 is provided at the center of the cylindrical portion 32 and protrudes from the outer peripheral surface of the cylindrical portion 32. One end surface of the flange 33 is a flat surface 33b, and the other end surface is a tapered surface 33c. The flat surface 33b of the flange 33 faces a lock flange 38 described later. A scale such as a dial (FIG. 5) is provided on the tapered surface 33c of the flange 33 at equal intervals in the circumferential direction. One end of the cylindrical portion 32 is accommodated in the recess 16 of the tool body 11. The remaining part of the dial ring 31, that is, the flange 33 and the other end of the cylindrical part 32 are accommodated in the notch 15. The other end of the cylindrical portion 32 is covered with a disc cover member 34.

  A lock flange 38 is disposed between one tool body 11 in the axis C direction and the other flange 33 in the axis C direction. The lock flange 38 is formed in an annular shape, and a recess for receiving the wave spring 42 is formed in a portion of the flange 33 of the dial ring 31 facing the flat surface 33b. The wave spring 42 is annular, and the cylindrical portion 32 of the dial ring 31 is passed through the center hole of the wave spring 42. The wave spring 42 is contracted between the lock flange 38 and the flange 33 (of the dial ring 31), and urges the dial ring 31 in the direction of pulling out of the lock flange 38 (the other in the axis C direction). On the outer diameter side of the wave spring 42, a gap G opened in the direction of the axis C is interposed between the lock flange 38 and the flange 33 of the dial ring 31. As a modification (not shown), the gap G may be closed. In this case, the flat surface 33 b of the flange 33 of the dial ring 31 contacts the surface 38 c of the lock flange 38.

  Since the rotation of the cartridge body 21 is restricted by the flat surface 13g (FIG. 2), when the dial ring 31 is rotated, the cartridge body 21 moves in the axis C direction. Thereby, the protrusion amount (distance from the axis O to the cutting edge tip 41) of the cutting edge tip 41 is finely adjusted. Even if the dial ring 31 is rotated, the wave spring 42 is not elastically deformed, and the dial ring 31 does not move in the direction of the axis C.

  The recess 16 of the tool body 11 receives the one end side of the cylindrical portion 32 and accommodates a lock nut 36, a washer 37, and a lock flange 38. The recess 16 of the tool body 11 is formed at the bottom of the second stage. Of these, the deeper bottom surface 16b is connected to the through hole 14 at the center to form an annular surface. The shallow bottom surface is a flat annular surface 16c surrounding the deep bottom surface. The lock flange 38 is formed in an annular shape and contacts the annular surface 16c. The cylindrical portion 32 of the dial ring 31 is passed through the center hole of the lock flange 38. The lock nut 36 and the washer 37 are disposed closer to the bottom surface 16b than the lock flange 38. The lock flange 38 projects to the inner diameter side from the annular surface 16c and faces the bottom surface 16b like an inward flange.

  As shown in FIG. 2, a female screw hole 17 is provided on the outer edge of the recess 16. The countersunk screw 18 screwed into the female screw hole 17 presses the lock flange 38 toward the annular surface 16c. Thereby, the lock flange 38 is attached and fixed to the tool body 11.

  Returning to FIG. 3, the back surface 38b of the lock flange 38 is in surface contact with the annular surface 16c on the outer diameter side. Marks (triangular marks shown in FIG. 5) are formed on the surface 38c of the lock flange 38. Such a mark faces a scale engraved on the tapered surface 33c and displays the circumferential position and rotation angle of the dial ring 31.

  The cylindrical portion 32 of the dial ring 31 is formed with a male screw 32f on the outer periphery on one end side. An annular lock nut 36 is screwed onto the male screw 32f. One end of the cylindrical portion 32 is passed through an annular washer 37. The washer 37 is disposed between the lock nut 36 and the lock flange 38.

  FIG. 4 is a perspective view showing the washer 37 taken out. The washer 37 is basically a ring-shaped disk, but is a washer with a tongue including a ring portion 37c and a tongue portion 37t formed in a part in the circumferential direction. The tongue portion 37 t rises in the axial direction from the inner peripheral edge of the washer 37 and engages with a concave portion 32 d formed in a part in the circumferential direction of the cylindrical portion 32. The recessed portion 32d is provided on the outer peripheral surface of the cylindrical portion 32 and prevents the washer 37 from rotating. The relative rotation of the lock nut 36 that contacts one end surface of the washer 37 is restricted by the washer 37. For this reason, the lock nut 36 does not rotate carelessly and is prevented from being displaced in the direction of the axis C while being screwed onto the outer periphery of the cylindrical portion 32.

  Further, the relative displacement in the direction of the axis C is restricted by the engagement between the recess 32d and the tongue 37t. As a result, the lock flange 38 is held between the washer 37 and the flange 33 of the dial ring 31, and the center portion of the dial ring 31 in the axis C direction is normally held so as to overlap the position of the lock flange 38 in the axis C direction. Therefore, when the operator rotates the dial ring 31, the cartridge body 21 moves forward and backward in the direction of the axis C, and the protruding amount of the cutting edge tip 41 is finely adjusted. The adjustment operation of the cutting edge tip 41 is realized by the rotation of the dial ring 31. The lock nut 36 is covered with the dial ring 31 and the lock flange 38 and is not touched by the operator. Therefore, in normal use, the lock nut 36 is not rotated by the operator.

  Next, a structure for attaching the tool body 11 to the tool holder 19 will be described.

  FIG. 6 is a side view showing the tool holder 19 and the tool body 11 of the embodiment. FIG. 7 is an exploded view showing the tool holder 19 and the coupling portion 12 of the tool body 11. The tool holder 19 has a tapered shank part 51, a flange part 52, and an arbor 53. The taper shank 51 is formed in the rear end region of the tool holder 19 and is tapered toward the rear end. The flange portion 52 is formed to protrude from the tip end portion of the tapered shank portion 51 in the outer diameter direction. On the outer peripheral surface of the flange portion 52, a V-shaped groove is formed such that the center portion is recessed toward the inner diameter side than the front end side and the rear end side. The arbor 53 is a cylindrical portion that is formed in the tip region of the tool holder 19 and protrudes from the tip surface of the flange portion 52 in the tip direction. The arbor 53 may have a smaller diameter than the flange portion 52. As shown in FIG. 6, the arbor 53 has a constant outer diameter in the axial direction, or as a modification (not shown), the tip of the arbor 53 extends from the root of the arbor 53. May also be tapered. The taper shank part 51, the flange part 52, and the arbor 53 extend around the axis O.

  The tool body 11 is made of a light metal such as an aluminum alloy or duralumin. The tool holder 19 is made of steel and is also referred to as a head body because it is coupled to the tip of the arbor 53. A joining surface 12b is formed at the rear end portion of the tool body 11 and is directed toward the rear end side in the axis O direction.

  At the tip of the arbor 53, a joining surface 19c that is in surface contact with the joining surface 12b of the tool body 11 is formed. The joint surface 19c is a front end surface of the arbor 53, and is also a front end surface of the tool holder 19, and is directed toward the front end side in the axis O direction. The joint surfaces 12b and 19c are annular flat surfaces perpendicular to the axis O. A coupling hole 55 is provided at the center of the joint surface 19c. The coupling hole 55 is a round hole extending rearward about the axis O, and receives the cylindrical coupling shaft portion 12c.

  A female screw hole 56 is further provided at the tip of the arbor 53. The female screw hole 56 extends from the outer peripheral surface of the arbor 53 to the inner peripheral surface of the coupling hole 55 at a right angle to the axis O and extends in the radial direction. A tapered taper hole 57 is formed on the side surface of the coupling shaft portion 12c. The clamp taper hole 57 is a bottomed hole, and its side surface is a taper that narrows toward the hole bottom. The clamping taper hole 57 also extends in the radial direction about the axis O and is perpendicular to the axis O. In the present embodiment, each of the female screw holes 56 and each of the clamp taper holes 57 are arranged so as to face each other at a position that differs by 180 ° in the circumferential direction. However, the arrangement and number of each female screw hole 56 and each taper hole 57 for clamping are not limited to this. When the coupling hole 55 receives the coupling shaft portion 12 c of the tool body 11, the female screw hole 56 is connected to the clamping taper hole 57. A clamp screw 58 having a tapered tip taper 59 is screwed into each female screw hole 56.

  As shown in FIG. 7, with respect to the rear end portion of the tool main body 11, a distance d <b> 1 is defined from the joining surface 12 b oriented toward the rear end side to the center of the taper hole 57 for clamping. Further, with respect to the distal end portion of the arbor 53, the distance d2 is from the joint surface 19c directed toward the distal end side to the center of the female screw hole 56. In the present embodiment, d1 <d2, and the interval d2 is slightly larger than the interval d1. Slightly large here means that the central axis of the taper hole 57 for clamping passes through the female screw hole 56 and the central axis of the female screw hole 56 passes through the taper hole 57 for clamping. It extends in parallel (the same applies hereinafter).

  When the clamp screw 58 is screwed into the female screw hole 56 from the outer diameter side, the tip taper 59 of the clamp screw 58 enters the clamp taper hole 57 and presses the coupling shaft portion 12c. Then, the taper surface 59t on the rear end side in the axis O direction of the entire circumference of the tip taper 59 comes into contact with the taper surface 59q on the rear end side in the axis O direction of the entire circumference of the taper taper hole 57 for clamping. By the pressing per piece, the coupling shaft portion 12 c is pulled backward in the direction of the axis O, and the joining surface 12 b of the tool body 11 is in close contact with the joining surface 19 c of the tool holder 19.

  According to the present embodiment, since the tool body 11 to which the cartridge body 21 is mounted is made of a light metal such as an aluminum alloy, the boring head portion of the boring bar can be reduced in weight. As a result, even if the boring head and arbor are rotated at a high speed during precision finishing of the workpiece, the centrifugal force of the boring head is smaller than that of the conventional steel, so the arbor is the centrifugal force of the boring head. It becomes difficult to be affected. As a result, it is possible to prevent the arbor from causing slight vibrations and chattering.

  Further, according to the present embodiment, the tool main body 11 is detachably coupled to the tip of the arbor 53 by the coupling portion 12 and the clamp screw 58 serving as coupling means with the axis O aligned with each other. It is easy to replace the boring head including the arbor 53, and the arbor 53 can be used for different types of boring heads.

  Further, according to the present embodiment, the interval d1 from the center of the clamp taper hole 57 to the bonding surface 12b is set smaller than the interval d2 from the center of the female screw hole 56 to the bonding surface 19c, whereby the bonding surface 19c of the arbor 53 is set. And the joining surface 12b of the tool main body 11 can be in close contact with each other, and the arbor 53 and the tool main body 11 can be securely and firmly connected to each other.

  Moreover, the boring tool 10 of this embodiment is a center through coolant type as shown in FIG. 6, and has a series of passages 71, 72, 73, 74 and a jet hole 75 through which the coolant passes. The passage 71 is formed inside the tool holder 19 and extends along the axis O from the bottom of the coupling hole 55 to the rear end of the tapered shank portion 51. The passage 72 is formed inside the tool body 11 and extends along the axis O from the rear end of the coupling shaft portion 12c toward the front end side. The tip of the passage 72 is connected to one end of the passage 73. Note that the front end of the passage 71 and the rear end of the passage 72 are connected to each other with no gap as the arbor 53 and the tool body 11 are coupled.

  The passage 73 is formed inside the tool body 11 and extends in the direction perpendicular to the axis O. The other end of the passage 73 is connected to the rear end of the passage 74. The passage 74 is formed inside the tool body 11 and extends parallel to the axis O. The tip of the passage 74 is connected to the ejection hole 75. The ejection hole 75 has a smaller diameter than the passages 71 to 74 described above, is formed in the chip pocket 13, and is directed to the cutting edge chip 41. Thereby, the coolant can be supplied from the boring tool 10 to the cutting portion in the boring operation of the workpiece. Further, the coolant passing through the passages 71 to 74 is increased in pressure when passing through the small-diameter ejection holes 75 and ejects vigorously from the ejection holes 75. Therefore, the cutting edge tip 41 and the workpiece can be sufficiently cooled during boring.

  Next, the structure which mounts the tool main body 11 to the tool holder 19 which becomes 2nd Embodiment of this invention is demonstrated.

  FIG. 8 is a side view showing the tool holder 19 and the tool body 11 of the second embodiment. FIG. 9 is an exploded view showing the tool holder 19 and the tool body 11. About 2nd Embodiment, about the structure which is common in embodiment mentioned above, the same code | symbol is attached | subjected and description is abbreviate | omitted, and a different structure is demonstrated below. The second embodiment differs from the first embodiment described above in that the tool body 11 and the arbor are connected to the rear end of the tool body 11 made of a light alloy material and the tip of the arbor 53 by a coupling means including a steel adapter 61. It is in the place which connected so that separation of the 53 axis lines O was possible.

  A steel adapter 61 is interposed between the joining surface 19 c of the arbor 53 and the joining surface 12 b of the tool body 11. The adapter 61 is an integral body, and the axis line coincides with the disc-shaped flange 62 interposed between the joining surface 19 c of the arbor 53 and the joining surface 12 b of the tool body 11, and both flange end surfaces 62 c and 62 b of the flange 62. The connecting shaft portions 63 and 65 on the front end side and the rear end side are provided so as to project. Both flange end surfaces 62c and 62b are annular flat surfaces perpendicular to the axis O.

  Further, the tool body 11 is formed with a coupling hole 12d which is a round hole extending from the center of the joining surface 12b to the tip side. The coupling hole 12d receives the cylindrical coupling shaft portion 63. Similarly, the coupling hole 55 of the tool holder 19 receives a cylindrical coupling shaft portion 65. The coupling shafts 63 and 65 are solid, but a coolant passage (not shown) may be provided.

  Further, a female screw hole 12 f is formed at the rear end of the tool body 11. The female screw hole 12f extends radially from the outer peripheral surface of the tool body 11 to the inner peripheral surface of the coupling hole 12d at a right angle to the axis O. A clamp taper hole 67 is formed on the outer peripheral surface of the coupling shaft portion 63. The clamp taper hole 67 is a bottomed hole, and its side surface is formed into a taper that narrows toward the hole bottom. The clamping taper hole 67 also extends in the radial direction about the axis O and is perpendicular to the axis O.

  In the second embodiment, each of the female screw holes 12f and each of the clamp taper holes 67 are arranged so as to face each other at a position different by 180 ° in the circumferential direction. However, the arrangement and the number of the female screw holes 12f and the clamp taper holes 67 are not limited thereto. When the coupling hole 12 d of the tool body 11 receives the coupling shaft portion 63 of the adapter 61, the female screw hole 12 f is connected to the clamping taper hole 67. A clamp screw 68 having a tapered tip taper 69 is screwed into each female screw hole 12f. The clamp screw 68 has the same shape as the clamp screw 58 described above.

  As shown in FIG. 9, with respect to the rear end portion of the tool main body 11, the distance d4 extends from the joint surface 12b directed to the rear end side to the center of the female screw hole 12f. Further, with respect to the distal end portion of the adapter 61, a distance d3 is defined from the flange end surface 62c directed to the distal end side to the center of the taper hole 67 for clamping. In the second embodiment, d3 <d4, and the interval d4 is slightly larger than the interval d3.

  When the clamp screw 68 is screwed into the female screw hole 12f from the outer diameter side, the tip taper 69 of the clamp screw 68 enters the clamp taper hole 67 and presses the coupling shaft portion 63 by the contact of both tapers. Then, the taper surface 69s on the tip side in the axis O direction on the entire circumference of the tip taper 69 comes into contact with the taper surface 67p on the tip side in the axis O direction on the whole circumference of the taper hole 67 for clamping. By such pressing per piece, the coupling shaft portion 63 is drawn into the bottom of the coupling hole 12d (the direction in the direction of the axis O), and the joining surface 12b of the tool body 11 is brought into close contact with the flange end surface 62c on the distal end side of the adapter 61.

  The connection between the rear end portion of the adapter 61 and the arbor 53 is also as described above with reference to FIG. 7, and the flange end surface 62 b on the rear end side of the adapter 61 is in close contact with the joining surface 19 c of the tool holder 19.

  According to the second embodiment, since the tool main body 11 to which the cartridge main body 21 is mounted is made of a light metal such as an aluminum alloy, a tool that is not easily affected by centrifugal force even if it rotates at a high speed as in the first embodiment. Can be provided. Further, with respect to the tool main body 11 which becomes the head main body of the boring bar, the natural frequency of the tool main body 11 is increased because the rear end of the tool main body 11 and the front end of the arbor 53 are connected by the connecting means including the steel adapter 61. The chatter stability limit of the boring head is improved.

  Further, according to the second embodiment, by using the adapter 61 having another structure, it becomes easy to process the coupling means of the tool body 11 and the tool holder 19 including the adapter 61, and the arbor is connected via the steel adapter 61. 53 and the tool main body 11 can be detachably coupled. As a result, even if the tool body 11 that becomes the boring head portion is frequently replaced, the coupling portion 12 is less worn and deformed compared to the first embodiment in which the boring head portion is directly coupled to the arbor, and the boring head portion and the arbor It is possible to maintain the bonding accuracy and bonding strength.

  According to the second embodiment, the tool body 11 is set by setting the distance d3 from the center axis of the taper hole 67 for clamping to the flange end face 62c to be smaller than the distance d4 from the center axis of the female screw hole 12f to the joint surface 12b. The joint surface 12b and the flange end surface 62c of the adapter 61 can be brought into close contact with each other, and the connection between the tool body 11 and the adapter 61 can be surely and strengthened.

  Similarly, by setting the distance d1 from the central axis of the clamp taper hole 57 to the flange end face 62b to be smaller than the distance d2 from the central axis of the female screw hole 56 to the joint surface 19c, the joint surface 19c of the arbor 53 and the adapter 61 are set. The flange end surfaces 62b of the arbor 53 and the adapter 61 can be securely and firmly connected to each other.

  Next, the structure which mounts the tool main body 11 to the tool holder 19 which becomes 3rd Embodiment of this invention is demonstrated.

  FIG. 10 is a side view showing the tool holder 19 and the tool body 11 of the third embodiment. FIG. 11 is an exploded view showing the tool holder 19 and the tool body 11. In the third embodiment, the same components as those in the above-described embodiment are denoted by the same reference numerals, description thereof is omitted, and different configurations are described below. The third embodiment differs from the second embodiment described above in that a steel adapter 66 that connects the rear end of the tool body 11 made of a light alloy material and the front end of the arbor 53 is half of the tool body 11. It is in a place where it can be fixedly connected.

  The adapter 66 includes a flange 62 interposed between the joint surface 19 c of the arbor 53 and the joint surface 12 b of the tool body 11, a coupling shaft portion 65 protruding from the flange end surface 62 b on the rear end side of the flange 62, and the tip of the flange 62. An inlay portion 63g protruding from the flange end surface 62c on the side and a screw portion 63i protruding from the axial center portion of the inlay portion 63g are provided. The coupling shaft portion 65, the spigot portion 63g, and the screw portion 63i have the same axis.

  In the tool main body 11 as the head main body, a circular engagement recess 12h into which the circular inlay portion 63g is fitted and a screw hole 12j into which the screw portion 63i is screwed are formed in the axial center portion of the joint surface 12b. .

  In the third embodiment, when the tool main body 11 is coupled to the joint surface 19c that becomes the distal end surface of the arbor 53, first, the screw portion 63i of the adapter 66 is screwed into the screw hole 12j of the tool main body 11 and tightened. The inlay portion 63g of the adapter 66 is fitted into the engagement recess 12h of the tool body 11 to ensure concentricity between the tool body 11 and the adapter 66, and the flange 62 of the adapter 66 is brought into close contact with the joining surface 12b of the tool body 11. Thus, the adapter 66 and the tool body 11 are coupled in a semi-fixed state.

  Next, after the coupling shaft portion 65 of the adapter 66 is fitted into the coupling hole 55 of the arbor 53, the coupling shaft portion 65 is tightened by screwing the clamp screw 58 into each female screw hole 56. At this time, the distance d1 from the center axis of the clamp taper hole 57 to the flange end face 62b of the flange 62 is set slightly smaller than the distance d2 from the center axis of the female screw hole 56 of the arbor 53 to the joint surface 19c. When the front end taper 59 is pushed into the clamping taper hole 57 of the coupling shaft portion 65 by screwing the clamp screw 58, the coupling shaft portion 65 is pulled in the depth direction of the coupling hole 55 by the action of both tapers, and the flange The flange end surface 62b of 62 and the joint surface 19c of the arbor 53 are joined in a state of being in close contact with each other.

  According to the third embodiment, the same effect as that of the second embodiment can be obtained, and the adapter 66 and the tool body 11 as the head body can be screwed in by providing the adapter 66 with the inlay portion 63g and the screw portion 63i. Can be easily combined.

  Next, the structure which mounts the tool main body 11 to the tool holder 19 which becomes 4th Embodiment of this invention is demonstrated.

  FIG. 12 is a side view showing the tool holder 19 and the tool body 11 of the fourth embodiment. FIG. 13 is an exploded view showing the tool holder 19 and the tool body 11. In the fourth embodiment, the same components as those in the above-described embodiment are denoted by the same reference numerals, description thereof is omitted, and different configurations are described below. In the fourth embodiment, as a point different from the third embodiment described above, a steel adapter 76 that connects the rear end of the tool main body 11 made of a light alloy material and the front end of the arbor 53 is an adapter for the tool main body 11. It is in a place where it can be semi-fixedly connected by a bolt 77 from the inside of 76.

  4th Embodiment has the steel adapter 76 which joins the joining surface 19c with the arbor 53, and the joining surface 12b of the tool main body 11 by making an axis line mutually correspond. The adapter 76 includes a flange 62 interposed between the joint surface 19c of the arbor 53 and the joint surface 12b of the tool body 11, a cylindrical coupling shaft portion 65 projecting from the flange end surface 62b on the rear end side of the flange 62, and a flange. An inlay portion 63g projecting from the flange end surface 62c on the distal end side of 62, and a through hole 76h that penetrates the flange 62 and the inlay portion 63g in the axial direction and is connected to the inner space 65n of the coupling shaft portion 65 are provided. The inner diameter of the through hole 76h is smaller than the inner diameter of the inner space 65n and is connected to the bottom surface of the inner space 65n. The coupling shaft portion 65, the spigot portion 63g, and the through hole 76h have the same axis. The inner peripheral surface of the coupling shaft portion 65 defines an inner space 65n as a round hole.

  A clamp bolt 77 is inserted into the through hole 76h from the rear of the axis O. The inner diameter of the through hole 76 h is smaller than the inner peripheral surface of the coupling shaft portion 65. Therefore, the head of the clamp bolt 77 is locked to the bottom of the inner space 65n. The shaft portion of the clamp bolt 77 protrudes from the through hole 76h and is screwed into a screw hole 12k formed in the bottom surface of the engagement recess 12h. The screw hole 12k extends along the axis O.

  In the fourth embodiment, when the tool main body 11 as the head main body is coupled to the tip of the arbor 53, first, the spigot portion 63g of the adapter 76 is fitted into the engaging recess 12h of the tool main body 11, and then formed into a cylindrical shape. The clamp bolt 77 inserted from the inner space 65n of the coupling shaft portion 65 is screwed into the screw hole 12k through the flange 62 and the spigot portion 63g and tightened. Thereby, the concentricity of the tool body 11 and the adapter 76 is secured by the spigot portion 63g, and the adapter 62 and the tool body 11 are semi-fixed by bringing the flange 62 of the adapter 76 into close contact with the joining surface 12b of the tool body 11. Join the state.

  Next, after fitting the coupling shaft portion 65 of the adapter 76 into the coupling hole 55 of the arbor 53, the coupling shaft portion 65 is tightened by screwing the clamp screw 58 into each female screw hole 56. At this time, the distance d1 from the center axis of the clamp taper hole 57 to the flange end face 62b of the flange 62 is set slightly smaller than the distance d2 from the center axis of the female screw hole 56 of the arbor 53 to the joint surface 19c. When the front end taper 59 is pushed into the clamping taper hole 57 of the coupling shaft portion 65 by screwing the clamp screw 58, the coupling shaft portion 65 is pulled in the depth direction of the coupling hole 55 by the action of both tapers, and the flange The flange end surface 62b of 62 and the joint surface 19c of the arbor 53 are joined in a state of being in close contact with each other.

  According to the fourth embodiment, the same effects as those of the second and third embodiments described above can be obtained, and the adapter 76 and the tool body 11 are coupled by the clamp bolt 77. The clamp bolt 77 extends from the inner space 65n of the coupling shaft 65 formed in a cylindrical shape along the axis of the flange 62 and the axis of the spigot portion 63g, and penetrates the flange 62 and the spigot portion 63g. As a result, the taper hole for clamping and the female screw hole described above do not have to be provided at a predetermined position in the circumferential direction, and there is no need to consider the rotational balance of the connection point between the adapter 76 and the tool body 11.

  In addition, the various structures with which the coupling | bonding means of 1st-4th embodiment mentioned above are each can be combined suitably in the modification which is not shown in figure.

  Next, a boring tool according to a fifth embodiment of the present invention will be described.

  FIG. 14 is a partial side view showing a boring head portion of a boring tool according to a fifth embodiment of the present invention, in which a part of the boring tool is cut along a cutting plane including an axis O of the boring tool. Represents. FIG. 15 is a cross-sectional view showing the tool body of FIG. 14 and shows a state in which the tool body is cut along a flat surface perpendicular to the axis O and the section is viewed in the direction of the axis O. In the fifth embodiment, the same components as those in the above-described embodiment are denoted by the same reference numerals, description thereof is omitted, and different configurations are described below. The fifth embodiment is different from the first embodiment in that a balance adjusting weight 81 is provided on the tool body 11.

  As shown in FIG. 14, a circular hole 11d having a predetermined diameter is formed on the outer peripheral surface of the rear end region of the tool body 11 at a circumferential position located on the side opposite to the tip pocket 13 and the head 22 of the cartridge body 21. Form. As shown in FIG. 15, the circumferential position of the circular hole 11 d overlaps with the notch 15 formed on the outer peripheral surface of the tip region of the tool body 11.

  When the tool body 11 is made of an aluminum alloy, a disc-shaped balance adjustment weight 81 made of lead or the like is inserted into the circular hole 11d. Is fixed to the tool body 11 with a fixing screw 82. As shown in FIG. 1, the head 22 of the cartridge body 21 is received in the chip pocket 13, and the leg portion 23 of the cartridge body 21 protrudes into the notch 15. For this reason, the balance adjustment weight 81 is attached to a circumferential position on the outer peripheral surface of the tool main body 11 that is far from the head 22 (chip pocket 13) of the cartridge main body 21 and close to the leg portion 23 (notch 15) of the cartridge main body 21. It is done.

  The weight of the balance adjusting weight 81 is set according to the weight of the head 22 of the cartridge main body 21 and the protruding amount in the radial direction from the axis O to the head 22. Fine adjustment of the rotational balance of the tool body 11 is performed by partially scraping the balance adjustment weight 81. As shown in FIG. 15, it is preferable that the circular hole 11 d is formed slightly shifted from the opposite position on the opposite side that is 180 ° in the circumferential direction from the head 22. Specifically, as shown in FIG. 15, the circular hole 11d is not provided in parallel to the axis C, and is brought closer to the chip pocket 13 side in the circumferential direction.

  According to the fifth embodiment, even when a boring unit including the cartridge body 21, the cutting edge tip 41, the dial unit 31 and the like is mounted on the tool body 11 made of a light alloy, the rotation balance of the tool body 11 is balanced. The balance adjustment weight 81 can be used for reliable adjustment. Along with this, the boring head and arbor can be rotated at high speed, and high-speed precision finishing of workpieces without the influence of centrifugal force and chatter can be easily realized.

  By the way, according to the first embodiment, the lock flange 38 is attached and fixed to the tool body 11 by the flat head screw 18. Further, the lock nut 36 and the washer 37 as the locked portion are attached and fixed to the leg portion 23 of the cartridge main body 21 via the dial ring 31. The back surface 38b of the lock flange 38 contacts the other end surface of the washer 37 on the inner diameter side. As a result, the lock nut 36 and the washer 37 as the locked parts are prohibited from coming out from the recess 16 to the outer diameter side of the tool body 11 by the lock flange 38. Accordingly, when the workpiece is bored, even if an external force F acts on the cutting edge tip 41 from the workpiece in the inner diameter direction of the tool body 11 as shown by a thick arrow in FIG. The cartridge main body 21 and the cutting edge tip 41 do not move in the axis C direction. According to the present embodiment, the cutting edge tip 41 does not move even when receiving an excessive external force F depending on the material of the workpiece and the cutting conditions, and the workpiece is bored with a desired boring diameter. be able to.

  Further, according to the first embodiment, the cartridge main body 21 and the dial ring 31 are prohibited from moving in the direction of the axis C due to the contact between the locked portion and the lock flange 38. That is, even if an excessive external force F acts on the cutting edge tip 41 in the direction of the axis C, the external force F is received by the lock flange 38 and does not act on the wave spring 42. Thus, even if the external force F is excessive, the wave spring 42 is not compressed and deformed, so the spring constant of the wave spring 42 may be small. The wave spring 42 as a soft elastic member presses the flange 33 of the dial ring 31 to the other side in the axis C direction with a small urging force. Therefore, the operator can manually rotate the dial ring 31 with a small torque, and can easily finely adjust the protruding amount of the cutting edge tip 41.

  Moreover, according to 1st Embodiment, the one lock nut 36 and the washer 37 which let the cylindrical part 32 of the dial ring 31 pass are included as a to-be-locked part, and the washer 37 is a washer with a tongue. As a result, the rotation of the washer 37 can be restricted by the tongue portion 37 t formed at a part in the circumferential direction of the washer 37. Further, the displacement of the washer 37 as viewed from the dial ring 31 can be restricted. The dial ring 31 can be allowed to rotate while holding the dial ring 31 in a relatively undisplaceable state when viewed from the tool body 11, and the cartridge body 21 is moved forward and backward along the through hole 14 by the rotation of the dial ring 31. Can be.

  Alternatively, as a modification (not shown), the washer 37 may be changed to a lock nut, and two lock nuts may be screwed into the male screw 32f as a locked portion. Thus, the locked part is constituted by a double lock nut. By tightening the two lock nuts so as to press each other, the locked portion is prevented from loosening and fixed to the dial ring 31.

  Moreover, according to 1st Embodiment, it has the passages 72-74 and the ejection hole 75 which are formed in the tool main body 11, as shown in FIG. The passages 72 to 74 and the ejection holes 75 are connected in series in this order, and the coolant passes therethrough. The series of passages 72 to 74 extend from the rear end portion of the tool body 11 to the ejection hole 75. The ejection hole 75 is formed at the tip of the tool body 11 and is directed toward the cutting edge tip 41. Thereby, in boring, a sufficient amount of coolant can be supplied to the cutting edge tip 41 and the workpiece.

  Moreover, according to 2nd Embodiment, as shown in FIG. 8, the arbor 53 and the steel adapter 61 which connects the front-end | tip part of the arbor 53 and the rear-end part of the tool main body 11 coaxially are further provided. The adapter 61 is formed between the joining surface 19c of the arbor formed at the distal end portion of the arbor 53 and directed toward the distal end side, and the joining surface 12b of the tool body formed at the rear end portion of the tool body 11 and directed toward the rear end side. Flange 62, a front end side coupling shaft portion 63 projecting from the flange end surface 62c on the front end side of the flange 62, and a rear end side coupling shaft portion 65 projecting from the flange end surface 62b on the rear end side of the flange 62. The arbor 53 is formed at the center of the joining surface 19 c of the arbor 53 and receives the coupling hole 55 of the arbor 53 that receives the coupling shaft portion 65 on the rear end side, and the outer circumferential surface of the arbor 53 from the inner circumferential surface of the coupling hole 55 of the arbor 53. And at least one internal thread hole 56 for clamping, which is coupled to the adapter 61 by a clamp screw 58 being screwed into the internal thread hole 56 for clamp. The tool body 11 is formed at the center of the joint surface 12b of the tool body 11 and is connected to the tool body 11 from the inner peripheral surface of the joint hole 12d of the tool body 11 that receives the joint shaft 63 on the distal end side and the joint hole 12d of the tool body 11. 11 and at least one clamping female screw hole 12f extending to the outer peripheral surface, and the clamp screw 68 is screwed into the clamping female screw hole 12f to couple with the adapter 61.

  This makes it possible to reduce the weight of the boring head portion of the boring tool 10 that is a boring bar, provide a tool that is not easily affected by centrifugal force even when rotating at high speed, and provide the tool main body 11 and the tip of the arbor 53 that become the head main body. By connecting the gaps with the connecting means including the steel adapter 61, the natural frequency of the head body is increased, and the chatter stability limit of the boring head portion can be improved.

  Further, according to the second embodiment, as shown in FIG. 8, the tip of the clamp screw 68 of the tool body 11 and the tip of the clamp screw 58 of the arbor 53 are tapered tip tapers 59 and 69. A clamping taper hole 67 connected to the clamping female screw hole 12f of the tool body 11 is formed on the outer peripheral surface of the coupling shaft portion 63 on the distal end side. A clamp taper hole 57 connected to the clamp female screw hole 56 of the arbor 53 is formed on the outer peripheral surface of the coupling shaft portion 65 on the rear end side. As shown in FIG. 9, the distance d3 from the flange end surface 62c on the distal end side to the central axis line of the tapered taper hole 67 on the distal end side is the central axis line of the female screw hole 12f for clamping on the tool body 11 from the joint surface 12b of the tool body 11. Is smaller than the interval d4. The distance d1 from the flange end face 62b on the rear end side to the central axis of the clamp taper hole 57 on the rear end side is smaller than the distance d2 from the arbor joint surface to the central axis of the female screw hole for arbor clamp. When the tip taper 69 of the clamp screw 68 enters the clamping taper hole 67 and the taper 69s and the taper 67p come into contact with each other, the coupling shaft portion 63 on the distal end side is drawn into the coupling hole 12d of the tool body 11 to The joint surface 12b and the flange end surface 62c on the front end side are brought into close contact, and the front end taper 59 of the clamp screw 58 enters the clamp taper hole 57 so that the taper 59t and the taper 57q come into contact with each other, so that the coupling shaft on the rear end side The portion 65 is drawn into the coupling hole 55 of the arbor 53 so as to achieve close contact between the joining surface 19c of the arbor 53 and the flange end surface 62b on the rear end side.

  Thereby, the joint surface 19c of the arbor 53 and the flange end surface 62b of the adapter 61 can be brought into close contact with each other, the flange end surface 62c of the adapter 61 and the joint surface 12b of the tool main body 11 can be brought into close contact with each other, and the arbor 53 and the tool main body 11 are coupled. It can be made surely and firmly.

  Moreover, according to 3rd Embodiment, as shown in FIG. 10, the arbor 53 and the steel adapter 66 which connects the front-end | tip part of the arbor 53 and the rear-end part of the tool main body 11 coaxially are further provided. The adapter 66 is formed between the joining surface 19c of the arbor 53 formed at the distal end portion of the arbor 53 and directed toward the distal end side, and the joining surface 12b of the tool body 11 formed at the rear end portion of the tool body 11 and directed toward the rear end side. , A flange portion 62g protruding from the flange end surface 62c on the front end side of the flange 62, a screw portion 63i protruding from the spigot portion 63g, and a rear end side protruding from the flange end surface 62b on the rear end side of the flange 62. And a coupling shaft portion 65. The arbor 53 is formed at the center of the joining surface 19 c of the arbor 53 and receives the coupling hole 55 of the arbor 53 that receives the coupling shaft portion 65 on the rear end side, and the outer circumferential surface of the arbor 53 from the inner circumferential surface of the coupling hole 55 of the arbor 53. And at least one clamping female screw hole 56 extending to the clamp 66, and the clamp screw 58 of the arbor 53 is screwed into the female screw hole 56 to be coupled to the adapter 66. The tool main body 11 is formed at the center of the joint surface 12b of the tool main body 11 and engages with the recessed portion 12g and the screw hole formed at the bottom surface of the engaging concave portion 12h and screwed with the screw portion 63i. 12j, and the screw portion 63i is screwed into the screw hole 12j to be coupled to the adapter 66.

  Thereby, in addition to the effect mentioned above, the adapter 66 and the tool main body 11 can be easily combined by the screwing method.

  Moreover, according to 4th Embodiment, as shown in FIG. 12, the arbor 53 and the steel adapter 76 which connects the front-end | tip part of the arbor 53 and the rear-end part of the tool main body 11 coaxially are further provided. The adapter 76 is formed between the joining surface 19c of the arbor 53 formed at the distal end portion of the arbor 53 and directed toward the distal end side, and the joining surface 12b of the tool body 11 formed at the rear end portion of the tool body 11 and directed toward the rear end side. The flange 62 interposed in the flange 62, the spigot portion 63g protruding from the flange end surface 62c on the front end side of the flange 62, the cylindrical coupling shaft portion 65 protruding from the flange end surface 62b on the rear end side of the flange 62, the flange 62 and the spigot portion 63g. Bolt through-holes 76h connected to the inner space 65n of the coupling shaft portion 65. The arbor 53 is formed at the center of the joint surface 19 c of the arbor 53 and receives at least one coupling hole 55 of the arbor 53 that receives the coupling shaft portion 65, and extends from the inner peripheral surface of the arbor 53 to the outer peripheral surface of the arbor 53. It has two female screw holes 56 for clamping, and the clamp screw 58 is screwed into the female screw hole 56 for clamping of the arbor 53 to couple with the adapter 76. The tool main body 11 is formed at the center of the joint surface 12b of the tool main body 11 and engages with an engagement recess 12h that engages with the spigot portion 63g, and a screw hole that is formed on the bottom surface of the engagement recess 12h and connects with the bolt through hole 76h. 12k, the shaft portion of the clamp bolt 77 is passed through the bolt through-hole 76h and screwed into the screw hole 12k, and the head of the clamp bolt 77 is engaged with the bottom surface of the inner space 65n to be coupled to the adapter 76. To do.

  As a result, the adapter 76 and the tool body 11 can be coupled with the clamp bolt that passes through the center of the adapter 76, and there is no need to consider the rotational balance of the coupling location.

  Further, according to the third and fourth embodiments, as shown in FIGS. 10 and 12, the distal end portion of the clamp screw 58 of the arbor 53 is formed into a tapered distal end tapered portion 59, and the coupling shaft portion 65 on the rear end side is formed. A clamp taper hole 57 connected to the clamp female screw hole 56 of the arbor 53 is formed on the outer peripheral surface. As shown in FIGS. 11 and 13, the central axis of the clamp taper hole 57 from the flange end surface 62b on the rear end side. Is smaller than the distance d2 from the joint surface 19c of the arbor 53 to the central axis of the female screw hole 56 for clamping of the arbor 53. When the tip taper 59 of the clamp screw 58 of the arbor 53 enters the clamp taper hole 57 and the taper 59t and the taper 57q come into contact with each other, the coupling shaft portion 65 on the rear end side is drawn into the coupling hole 55 of the arbor 53. 53 is configured to achieve close contact between the joint surface 19c of 53 and the flange end surface 62b on the rear end side.

  As a result, the joint surface 19c of the arbor 53 and the flange end surface 62b of the adapter 76 can be brought into close contact with each other, and the arbor 53 and the tool body 11 can be reliably and firmly coupled.

  Further, according to the fifth embodiment, as shown in FIGS. 13 and 14, the balance adjustment that is attached to the circumferential position far from the head of the cartridge body 21 and close to the legs of the cartridge body 21 on the outer circumferential surface of the tool body 11. Since the weight 81 for operation is further provided, even if the boring unit including the cartridge main body 21 and the like is mounted on the tool main body 11 made of a light alloy, the rotation balance of the tool main body 11 can be reliably adjusted by the balance adjusting weight 81. Can do. Accordingly, the tool main body 11 and the cartridge main body 21 as the boring head and the arbor 53 can be rotated at high speed, and high-speed precision finishing of the workpiece without the influence of centrifugal force and chatter can be easily realized.

  Although the embodiments of the present invention have been described with reference to the drawings, the present invention is not limited to the illustrated embodiments. Various modifications and variations can be made to the illustrated embodiment within the same range or equivalent range as the present invention.

  The boring tool according to the present invention is advantageously used in a machine tool.

10 boring tool, 11 tool body, 12 joint,
12b joint surface, 12c joint shaft part, 12d joint hole,
13 chip pockets, 14 through holes, 15 notches,
16 recesses, 18 countersunk screws, 19c joint surface,
21 cartridge body, 22 head, 23 leg,
31 dial ring, 32 cylindrical part,
33 Dial ring flange, 36 Lock nut (locked part),
37 Washer with tongue (locked part), 38 Lock flange,
41 cutting edge tip, 42 wave spring (elastic member),
53 Arbor, 58 Clamp screw, 61 Adapter,
62 flange, 63, 65 coupling shaft part, 63g spigot part,
71-74 passages, 75 ejection holes, 76 adapters,
77 clamp bolt, 81 balance adjustment weight,
O The axis of the boring tool, C The axis of the through hole 14.

Claims (10)

A tool body having a through hole;
A cartridge body having a head portion provided with a cutting edge tip and a leg portion passed through the through hole;
A dial ring having a cylindrical portion and a flange protruding from the cylindrical portion in an outer diameter direction, a female screw is formed on an inner periphery of the cylindrical portion, and screwed into a distal end portion of the leg portion protruding from the through hole; ,
A female threaded hole that engages with a male thread formed on the outer periphery of the cylindrical part, and a locked part disposed between the flange and the tool body;
A lock flange disposed between the locked portion and the flange and fixed to the tool main body and in contact with the locked portion;
A boring tool comprising: the lock flange and an elastic member interposed between the flanges and biasing the flange away from the lock flange.   The boring tool according to claim 1, wherein the locked portion includes two lock nuts.   The boring tool according to claim 1, wherein the locked portion includes one lock nut and an annular tongue washer passed through the cylindrical portion.   The coolant injection hole which is formed in the front-end | tip part of the said tool main body, and is directed to the said cutting-edge chip | tip, and the coolant channel | path which is formed in the said tool main body and extends from the rear-end part of the said tool main body to the said discharge hole is further provided. The boring tool according to any one of 1 to 3. An arbor mounted on the spindle of the machine tool;
A steel adapter that coaxially connects the tip of the arbor and the rear end of the tool body;
The adapter is formed at the front end portion of the arbor and has a flange interposed between the arbor joint surface directed toward the front end side and the tool body joint surface formed at the rear end portion of the tool body and directed toward the rear end side; A front end side coupling shaft portion projecting from the front end side flange end surface of the flange, and a rear end side coupling shaft portion projecting from the rear end side flange end surface of the flange;
The arbor is formed at the center of the arbor joint surface to receive an arbor coupling hole for the rear end side coupling shaft, and for at least one arbor clamp extending from an inner circumferential surface of the arbor coupling hole to an outer circumferential surface of the arbor A female screw hole, and the arbor clamp screw is screwed into the female screw hole for the arbor clamp to couple with the adapter,
The tool body is formed at the center of the tool body joint surface and has a tool body joint hole for receiving the distal end side coupling shaft portion, and at least one extending from an inner peripheral surface of the tool body joint hole to an outer peripheral surface of the tool body. The boring tool according to any one of claims 1 to 4, wherein the boring tool has two tool body clamping female thread holes, and is coupled to the adapter by screwing a tool body clamping screw into the tool body clamping female thread hole. The tip of the tool body clamp screw and the tip of the arbor clamp screw have a tapered tip taper,
On the outer peripheral surface of the tip side coupling shaft portion, a tip side clamping taper hole connected to the female screw hole for clamping the tool body is formed,
On the outer peripheral surface of the rear end side coupling shaft portion, a rear end side clamp taper hole connected to the female screw hole for arbor clamp is formed,
The distance from the tip end flange end surface to the center axis of the tip end clamping taper hole is smaller than the interval from the tool body joint surface to the center axis of the tool body clamping female screw hole,
The interval from the rear end side flange end surface to the central axis of the rear end side clamp taper hole is smaller than the interval from the arbor joint surface to the central axis of the arbor clamp female screw hole,
The tip end taper of the tool body clamp screw enters the tip end side clamping taper hole, and the both tapers come into contact with each other, thereby pulling the tip end side connecting shaft portion into the tool body connecting hole and the tool body joining surface. And close contact of the end flange surface,
The front end taper of the arbor clamp screw enters the rear end side clamping taper hole, and both tapers come into contact with each other, thereby drawing the rear end side connecting shaft portion into the arbor connecting hole, and the arbor joint surface and The boring tool according to claim 5, wherein the boring tool is configured to achieve close contact of the rear end flange end surface. An arbor mounted on the spindle of the machine tool;
A steel adapter that coaxially connects the tip of the arbor and the rear end of the tool body;
The adapter is formed at the front end portion of the arbor and has a flange interposed between the arbor joint surface directed toward the front end side and the tool body joint surface formed at the rear end portion of the tool body and directed toward the rear end side; An inlay portion protruding from a flange end surface of the front end side of the flange, a screw portion protruding from the inlay portion, and a rear end side coupling shaft portion protruding from a rear end side flange end surface of the flange;
The arbor is formed at the center of the arbor joint surface to receive an arbor coupling hole for the rear end side coupling shaft, and for at least one arbor clamp extending from an inner circumferential surface of the arbor coupling hole to an outer circumferential surface of the arbor A female screw hole, and the arbor clamp screw is screwed into the female screw hole for the arbor clamp to couple with the adapter,
The tool body has an engagement recess formed at the center of the tool body joint surface and engaged with the spigot portion, and a screw hole formed on the bottom surface of the engagement recess and screwed with the screw portion. The boring tool according to claim 1, wherein the screw portion is coupled to the adapter by being screwed into the screw hole. An arbor mounted on the spindle of the machine tool;
A steel adapter that coaxially connects the tip of the arbor and the rear end of the tool body;
The adapter is formed at the front end portion of the arbor and has a flange interposed between the arbor joint surface directed toward the front end side and the tool body joint surface formed at the rear end portion of the tool body and directed toward the rear end side; An inlay portion projecting from a flange end surface of the front end side of the flange, a cylindrical rear end side coupling shaft portion projecting from a flange end surface of the flange on the rear end side, and the rear end side passing through the flange and the inlay portion A bolt through hole connected to the internal space of the coupling shaft,
The arbor is formed at the center of the arbor joint surface to receive an arbor coupling hole for the rear end side coupling shaft, and for at least one arbor clamp extending from an inner circumferential surface of the arbor coupling hole to an outer circumferential surface of the arbor A female screw hole, and the arbor clamp screw is screwed into the female screw hole for the arbor clamp to couple with the adapter,
The tool body has an engagement recess formed at the center of the tool body joint surface and engaged with the spigot portion, and a screw hole formed on the bottom surface of the engagement recess and connected to the bolt through hole. The shaft portion of the clamp bolt is passed through the bolt through hole and screwed into the screw hole, and the head portion of the clamp bolt is engaged with the bottom surface of the internal space to couple with the adapter. The boring tool according to any one of -4. The tip of the arbor clamp screw has a tapered tip,
On the outer peripheral surface of the rear end side coupling shaft portion, a rear end side clamp taper hole connected to the female screw hole for arbor clamp is formed,
The interval from the rear end side flange end surface to the central axis of the rear end side clamp taper hole is smaller than the interval from the arbor joint surface to the central axis of the arbor clamp female screw hole,
The front end taper of the arbor clamp screw enters the rear end side clamp taper hole, and both tapers come into contact with each other, thereby drawing the rear end side connecting shaft portion into the arbor connecting hole, The boring tool according to claim 7 or 8, wherein the boring tool is configured to realize close contact of the rear end side flange end face.   10. The balance adjusting weight according to claim 1, further comprising a balance adjusting weight that is attached to a circumferential position of the outer peripheral surface of the tool body that is far from the head of the cartridge body and close to the legs of the cartridge body. Boring tools.

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