JP4141297B2 - Deep hole cutting tool - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a deep hole cutting tool such as a drill or a reamer applied to a gun drill system.
[0002]
[Prior art]
Gun drill systems, BTA systems, ejector systems, and the like are known as deep hole drilling systems, but gun drill systems with a simple configuration are widely used for deep hole drilling of relatively small diameters.
[0003]
As the gun drill system, generally, for example, the conventional techniques listed in Patent Document 1 or 2 can be cited. This structure will be described with reference to FIG. 6A. A drill head 32 is integrally fixed to the tip of a shank shaft 31 having a hollow cylindrical shape and having a V-shaped concave groove 34 along the longitudinal direction on the outer surface. A gun drill 30 in which the hollow portion of the shank shaft 31 is used as a coolant C supply passage 33 and the concave groove is used as a discharge groove 34 for the chips S is used. When drilling deep holes, high-pressure coolant C is supplied to the drill head 32 through the supply passage 33. The chip S is discharged from the front end side, and the chips S generated in the cutting hole H of the workpiece W are discharged to the outside through the discharge groove 34 together with the coolant C.
[0004]
[Patent Document 1]
Japanese Patent Publication No.59-12405 [Patent Document 2]
Japanese Utility Model Publication No. 60-53416
As shown in the sectional view of FIG. 5B, the gun drill used in the above-described gun drill system forms coolant C supply passages 33a and 33b in the hollow portion of the shank shaft 31, and cuts off the shank shaft 31. The coolant discharge groove 34 is formed by cutting the entire section in the axial direction so that the cross section forms a V shape of approximately 90 degrees with the shank axis O as the center, and the coolant discharge groove 34 is discharged in this way. The area is increased to provide a sufficient coolant discharge capacity. On the other hand, the cross-sectional area of the supply passages 33a and 33b of the coolant C formed in the vicinity of the shaft center of the shank shaft 31 cannot be made too large for reasons of strength. For this reason, for example, the coolant discharge area is reduced. Even if the discharge capacity is increased by increasing the discharge capacity, there is a limit to the supply capacity of the coolant C. Therefore, eventually, the chips S generated in the cutting hole H of the workpiece W are externally passed through the discharge groove 34 together with the coolant C. There was a certain limit to the discharge capacity.
[0006]
In addition, as described above, approximately one-fourth of the cross-sectional area of the shank shaft 31 is cut around the axis O, so that the cross-sectional area of the coolant discharge groove 34 is large. The coolant supply passages 33a and 33b formed in the vicinity of the shaft center 31 must inevitably become a single or a plurality of through passages 33a and 33b having a small diameter while avoiding the shaft center O of the shank shaft 31 as shown in the figure. For this reason, when the length of the shank shaft 31 exceeds 1.5 meters, it is difficult to maintain the straightness of the through passages 33a and 33b in the drilling process, and there is a problem in the production.
[0007]
[Problems to be solved by the invention]
The present invention has been made in view of the above problems, and by ensuring the formation of the coolant supply passage and the coolant discharge groove or the structure of the shank shaft, the shank shaft has sufficient strength and good accuracy. The purpose is to ensure the ease of manufacture and to improve the chip discharge capability by the coolant.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 is provided with the reference numeral shown in the embodiment, and a coolant discharge groove 1 is provided in the outer peripheral portion, and a coolant supply passage 2 is provided in the inside. A shank shaft 3 provided and a cutting head 4 at the tip of the shank shaft 3 are provided . A part of the outer peripheral wall is cut linearly from the shank shaft 3 to the tip of the cutting head 4, and the cut portion 8 is formed of coolant. a deep hole cutting tool that form a discharging groove 1, along the longitudinal direction intermediate portion of the cutting head 4 from the base side of the shank shaft 3, through hole 7 is the shank axis 3 to form a supply passage 2 of the coolant A plurality of coolant supply holes 6 c branched from the through hole 7 are formed from the middle in the longitudinal direction to the tip of the cutting head 4, and the coolant is provided on the tip surface of the cutting head 4. A plurality of discharge ports 15 communicating with the supply hole 6 c are provided, and the discharge groove 1 is formed so as to avoid the through hole 7 and the coolant supply hole 6 c, and extends from the shank shaft 3 to the longitudinal intermediate portion of the cutting head 4. The groove bottom part forms a concentric arcuate surface 8a concentric with the through-hole 7, and the groove bottom part has a V-shaped cross section in which the groove bottom part is located substantially at the center of the cutting head from the longitudinal middle part to the tip of the cutting head 4. those having the structure, characterized by comprising have a cutting edge (hard tip 17) across substantially the entire width of the cross section V-shaped one side to the cutting head 4 tip.
[0009]
According to the invention of claim 1, first, the through hole 7 is provided in the entire axial direction concentrically with the shank shaft 3, and this is used as the coolant supply passage 2 by using the through hole 7. The supply passage can be easily manufactured. In addition, this shank shaft 3 is applicable not only to the case where a plurality of shank shaft members 9 are screw-connected to each other as will be described later, but also to the case of a single long shank shaft. It is.
[0010]
Even when the through hole 7 is formed by drilling the central portion of the solid round shaft member in manufacturing, when the through hole 7 is formed concentrically (axial center) of the solid round shaft member, It is possible to perform drilling work by relative rotation between the real round shaft member and the drilling tool. Therefore, even if the solid round shaft member is a long member exceeding 1.5 meters, it has excellent straightness. A through hole which is a coolant supply passage can be formed, and a deep hole cutting tool with good accuracy can be easily manufactured.
[0011]
Furthermore, since the through-hole 7 is formed concentrically on the shank shaft 3 and this through-hole 7 is used as the coolant supply passage 2, the coolant supply passage 2 can be formed with a large diameter, and the supply capacity of the coolant is improved accordingly. Can be made. Thus, even if the coolant supply passage 2 is formed to have a large diameter, by reducing the cross-sectional area of the coolant discharge groove 1 formed by cutting the outer peripheral wall of the shank shaft 3 as much as possible as described later. The necessary and sufficient shaft strength can be ensured.
[0012]
Then, a part of the outer peripheral wall of the shank shaft 3 is cut away from the through-hole 7, that is, not to communicate with the through-hole 7, so as to cut out the entire region in the substantially axial direction. Therefore, since it is only necessary to cut a part of the shank shaft 3 in the axial direction from the viewpoint of production, the production is easy.
[0013]
Further, by cutting away a part of the outer peripheral wall of the shank shaft 3 while avoiding the through hole 7, a part of the outer peripheral surface 8a of the through hole 7 is exposed at the bottom of the cut part 8, Accordingly, the cut portion 8 is formed by a gap surrounded by the exposed outer peripheral surface 5a of the through hole 7 and the cut end surfaces 8b and 8c obtained by cutting a part of the shank shaft 3, and the cut portion 8 has a large diameter. Since the cross-sectional area of the coolant discharge groove having a V-shaped cross-section passing through the shaft center of the conventional shank shaft is smaller than that of the conventional through-hole 7 formed in Furthermore, coupled with the improvement of the coolant supply capacity of the coolant supply passage 2, even if the cross-sectional area of the coolant discharge groove is slightly reduced, the coolant flow rate is rather increased, and the chip discharge capacity can be significantly improved. it can.
[0014]
According to a second aspect of the present invention, the shank shaft 3 has a configuration according to the first aspect in which a cutting head 4 is detachably provided at a tip portion by screw coupling.
[0015]
According to the invention according to claim 2, when the cutting head 4 is provided so as to be detachable from the shank shaft 3, it is necessary to replace either one due to wear or chipping of the cutting head 4 or the shank shaft 3, Compared to a conventional one having a cutting head and a shank shaft, only the above-mentioned parts that are worn or missing need to be replaced.
[0016]
Further, when switching to another cutting operation such as drilling and reaming, only the cutting head 4 can be replaced and the shank shaft 3 can be used continuously.
[0017]
As described above, since the cutting head 4 is connected to the shank shaft 3 by screw connection, the connecting structure between the two can be manufactured easily and inexpensively, and either one at the time of wear or chipping can be produced. The parts can be easily replaced.
[0018]
According to a third aspect of the present invention, the shank shaft 3 includes a plurality of shank shaft members 9, and each of the shank shaft members 9 is detachably screw-coupled to each other. Is.
[0019]
According to the invention of claim 3, since the shank shaft 3 is composed of a plurality of shank shaft members 9 screwed together, if a plurality of different shank shaft members 9 are prepared, By changing the shank length, the shank shaft member 9A having the proximal-side driver portion 16 can be changed without changing the shank shaft member 9A. When the shank shaft member 9 is worn, broken, deformed, etc., only the shank shaft member 9 can be replaced and used continuously.
[0020]
In the invention according to claim 4, one of the screw coupling portions 10 on both sides of the shank shaft member 9 constitutes a male screw 5 d and the other constitutes a female screw 5 b, and the screw coupling portion between the shank shaft member 9 and the cutting head 4. 13 has the configuration according to claim 3 , wherein the shank shaft member 9 is set to have the same size and shape as the screw coupling portion 10 of each other.
[0021]
According to the fourth aspect of the invention, if necessary, a plurality of shank shaft members 9 are coupled at the screw coupling portion 10, or the cutting head 4 is coupled to the shank shaft member 9 at the screw coupling portion 13. Cutting can be performed.
[0022]
In the invention according to claim 5, the screw used for the screw coupling portions 10, 13 is a square screw, and the incomplete screw portion 13a on the end side of the male screw 5d and the open end side of the female screw 5b in the square screw is described above. It consists of a structure in any one of Claims 2-4 which exists in the formation range of the groove | channel 1 (1A, 1B, 1C) for coolant discharge | emission, and does not exist.
[0023]
According to the invention which concerns on Claim 5, if each screw engaging part 10 and 13 of the shank shaft member 9 or the shank shaft member 9 and the cutting head 4 is made into a square screw, a joint strength will become large and a clearance gap will be made. Since it is difficult to occur, leakage of the coolant from the screw engaging portions 10 and 13 can be prevented.
[0024]
Further, the incomplete thread portion 13a on the end side of the male screw 5d and the open end side of the female screw 5b in each of the thread engaging portions 10 and 13 of the shank shaft member 9 or the shank shaft member 9 and the cutting head are connected to the discharge groove 1. (1A, 1B, 1C) is in a state where it does not exist within the range of formation, so that a complete end face shaped screw end faces the cut end face forming the discharge groove 1 (1A, 1B, 1C), and a gap Therefore, it is possible to prevent a problem that chips are caught in the gap and cannot be discharged smoothly.
[0025]
In the invention according to claim 6, the coolant discharge groove 1 on the outer periphery of the shank shaft 3 has a depth L1 of the cut surface in a direction orthogonal to the shaft at a ratio of 1/2 to 1/4 of the shank shaft radius. And having a length L2 of approximately 1/3 to 1/5 of the entire circumference in the circumferential direction.
[0026]
According to the invention which concerns on Claim 6, although the discharge groove | channel 1 of coolant is formed in the part 6 by which a part of outer peripheral wall of the shank axis | shaft 3 was excised, the depth of the radial direction of the part, In other words, the depth L1 of the cut end faces 8b and 8c obtained by cutting the outer peripheral wall of the shank shaft 3 and the cut amount L2 of the outer peripheral wall in the circumferential direction of the shank shaft 3 can be freely set within the above range. Therefore, the discharge capacity of the chips S generated in the cutting hole H of the workpiece W can be freely adjusted.
[0027]
According to a seventh aspect of the present invention, the cutting head 4 is provided with one or a plurality of coolant discharge ports 15 in communication with the coolant supply passage 2 side on the shank shaft 3 side. It consists of the composition in any one.
[0028]
Since the cutting head 4 is provided with a cemented carbide tip as a cutting blade, the head body 4a must be formed with an opening having a V-shaped cross section of approximately 90 ° from the center. For this reason, it is not possible to form the supply passage 2 composed of the above-described cut portion 8 as formed in other portions. Therefore, in the present invention, the head main body 4a is provided with a central portion of the head main body 4a because the coolant outlet 15 is provided in communication with the coolant supply passage 2 on the shank shaft 3 side. The opening having a V-shaped section of approximately 90 ° can be formed, and the discharge ability of chips and coolant is not hindered.
[0029]
DETAILED DESCRIPTION OF THE INVENTION
Preferred embodiments of the deep hole cutting tool according to the present invention will be specifically described below with reference to the drawings.
[0030]
As shown in FIGS. 1A to 1C, a gun drill according to an embodiment of the present invention includes a base shank shaft member 9 </ b> A provided with a driver portion 16, and a screw coupling portion 10 at one end at the tip thereof. An intermediate shank shaft member 9B that is coupled and detachably connected in a coaxial manner, and a head portion shank shaft member 9C is screwed to the other end side of the intermediate portion shank shaft member 9 by a screw joint portion 13 and coaxial. It is comprised with the drill head 4 which is the cutting head for drilling connected so that attachment or detachment was possible. Note that a portion surrounded by B in FIG. 1A is shown in FIG. 1B, and a portion surrounded by C is enlarged in FIG. 1C.
[0031]
As shown in detail in FIGS. 2A to 2C, the proximal end side shank shaft member 9 </ b> A is provided with through holes 7 concentrically with the shank shaft 3 in substantially the entire axial direction. A coolant supply passage 2 is formed, and a part of the outer peripheral wall of the shank shaft 3 is cut linearly in the entire axial direction avoiding the through-hole 7, and the cut portion 8 forms the coolant discharge groove 1A. Do it.
[0032]
When the shank shaft member 9A is formed by using a long solid round shaft member, for example, when performing a drilling operation at the center of a solid round shaft member exceeding 1.5 meters, Since the drilling operation can be performed while relatively rotating the solid round shaft member, the shank shaft member 9A having good straightness can be easily manufactured. Note that a large-diameter driver portion 16 that receives a rotational driving force is integrally formed by coaxial cutting at the proximal end portion of the shank shaft member 9A.
[0033]
Further, as shown in FIGS. 2B and 2C, a part of the outer peripheral wall of the shank shaft member 9A is cut off substantially in the axial direction while avoiding the through-hole 7 to form a cutout portion 8. bottom surface of the part 8 forms a concentric convex arc surface 8a in the through hole 7, resected end face 8b of the cut portion and the convex arc surface 8a, cutouts 8 are surrounded by and 8c are formed,該切removal section 8 This forms the coolant discharge groove 1A.
[0034]
On the base side of the base shank shaft member 9A, as shown in FIG. 2A, a coolant discharge groove 1A, which is a cut-out portion 8, is provided along the longitudinal direction up to the vicinity of the large-diameter driver portion 16 on the base end side. At the same time, a connecting tube portion 5a is provided on the distal end side of the base shank member 9A, and a female screw 5b composed of a square screw is engraved on the inner side of the connecting tube portion 5a. Thus, as shown in FIGS. 2B and 2C, the discharge groove 1A has a cut-out portion 8 formed on the outer peripheral side of the base shank shaft member 9A with the shank axis O of the shank shaft 9A as the center. The cut end face 5e, 5f has a thickness L1 with a circumferential length L2 that opens approximately 90 °, and the cut wall 8a and the female screw 5b cut out the peripheral wall 5a1. Is formed. Further, the driver portion 16 is formed with a central hole 16a that reaches an intermediate position from the base end, and a through hole 6 that extends from the inner bottom of the central hole 10a to just before the female screw 5b of the connecting cylinder portion 5a of the base shank shaft member 9A. A coolant supply passage 2 is formed.
[0035]
As described above, as shown in FIGS. 2B and 2C, the cutout portion 8 that is the discharge groove 1A has the cutout portion 8 formed on the outer peripheral side of the base shank shaft member 9A. The cut end surface 5e, 5f is formed with a thickness L1 lacking in a circumferential length L2 that opens approximately 90 ° with respect to the center, and thus the discharge cross-sectional area of the discharge groove 1A is equal to the circumferential length L2. If the inner diameter of the through-hole 7 is constant, the circumferential length L2 determines the discharge cross-sectional area of the discharge groove 1A, and thus the coolant discharge capacity. Will be.
[0036]
The intermediate shank member 9B has a round cylindrical shape with the same outer diameter as that of the base shank member 9A described above. As shown in detail in FIGS. A through-hole 7 is formed in the through-hole 7 to form the coolant supply passage 2, and a part of the outer peripheral wall of the shank shaft 3 is cut out in a straight line substantially in the entire axial direction avoiding the through-hole 7. The cut portion 8 forms the coolant discharge groove 1B.
[0037]
The one end side of the intermediate shank member 9B has a connecting shaft portion 5c having an outer diameter that can be tightly fitted into the connecting tube portion 5a formed in the base shank member 9A. The connecting shaft portion 5c A male screw 5d made of a square screw threadedly engaged with the female screw 5d of the connecting tube portion 5a is engraved on the distal end side, and the other end side has the same size and shape as the connecting tube portion 5a of the base shank shaft member 9A. A connecting cylinder portion 5a is formed by engraving a female screw 5b made of a square screw. And the cool rank supply passage 2 which is the through-hole 6 formed in the shank shaft 3 is provided until one end thereof reaches immediately before the female screw 5b and the other end thereof reaches the front end surface of the male screw 5d.
[0038]
Thus, as shown in FIGS. 3 (B) and 3 (C), the discharge groove 1B has a cut portion 8 formed on the outer peripheral side of the intermediate shank shaft member 9B at approximately 90 ° about the shank axis O. The cut end face 5e, 5f is cut in the circumferential length L2 and the cut end portion 5e, 5f is cut off by the thickness L1, and the connecting tube 5a and the female screw 5b at the other end are cut off from the cut wall 5a1. 8 is formed, and the cutout portion 8 is formed by cutting out the peripheral wall 5c1 in the connecting shaft portion 5c and the male screw 5d at one end.
[0039]
Thus, as shown in FIGS. 1A and 1C, the base shank shaft member 9A and the intermediate shank shaft member 9B are connected to each other, that is, a connecting cylinder formed on the outer peripheral side of the base shank member 9A. The connecting shaft portion 5c formed on the outer peripheral side of the intermediate shank shaft member 9B is fully fitted and screwed to the portion 5a, and the stepped portion 5g on the base side of the connecting shaft portion 5c is in close contact with the end surface of the connecting cylinder portion 5a. Thus, the discharge grooves 1A and 1B are linearly connected to each other without any deviation, and the coolant supply passage 2 which is the through hole 6 formed in the base side shank member 9A and the through hole 6 formed in the intermediate shank shaft member 9B. The coolant supply hole 2 is set so as to communicate with each other, whereby the shank shaft 3 is formed.
[0040]
As shown in detail in FIGS. 4A to 4D, the drill head 4 has a head shank shaft member 9C formed on the base end side, and a connecting shaft portion 5c formed on the shaft member 9C. A male screw 5d made of a square screw that engages with the female screw 5b of the connecting tube portion 5a on the intermediate shank member 9B side is engraved on the distal end side of the shaft portion 5c, and a penetration formed in the head portion shank shaft member 9C. One end of the cool rank supply passage 2 which is the hole 7 reaches the end surface of a drill body 4b described later, and the other end reaches the end surface of the male screw 5d. Further, as shown in FIGS. 4 (C) and 4 (D), the discharge groove 1C is formed by cutting around the axis O of the head shank shaft member 9C, so that the connection shaft portion 5c and the male screw 5d are formed. The partial peripheral wall 5c1 is cut off in the same manner as the intermediate shank shaft member 9B.
[0041]
Then, the cutting edge side of the head main body 4b of the drill head 4 has become a solid, the real head main body 4b in this, a V-shaped discharge grooves 4c opened to approximately 90 ° about the axis is A cemented carbide tip 17 is formed by brazing or the like so as to face the one side surface of the discharge groove 4c, and forms a cutting blade extending over substantially the entire width of the one side surface. Two coolant supply holes 6c, 6c are formed in communication with the end surface of 5c, more precisely, the supply passage 2 which is a through hole 7 formed in the head shank shaft member 9C and reaches the front end surface 4d of the head body 4b. In addition, discharge ports 15 and 15 that are openings of both coolant supply holes 6c and 6c are opened in the tip surface 4d. In addition, guide pads 18 are fixed to two locations on the outer peripheral portion outside the discharge groove 4c.
[0042]
As shown in FIGS. 1 (A) and 1 (B), the drill head 4 is filled with the connecting shaft portion 5c formed on the head shank member 9C in the connecting tube portion 5a of the intermediate shank shaft member 9B. The discharge grooves 4c and 1C are straight without any deviation from the discharge groove 1B of the intermediate shank shaft member 9B in a state where the end surface of the connection cylinder portion 5a is in close contact with the step portion 5g on the base side of the connection shaft portion 5c. The coolant supply passage 2 on the drill head 4 side is set so as to communicate with the coolant supply hole 2 of the intermediate shank shaft member 9B. The connecting shaft 5c of the drill head 4 and the connecting shaft 5c of the intermediate shank shaft member 9B have the same size and shape.
[0043]
The distal end side of the internal threads 5b and 5b in the connecting cylinder portions 5a and 5a (FIGS. 2A and 3A) of the base side shank member 9A and the intermediate portion shank shaft member 9B, the intermediate portion shank shaft member 9B and the drill On the opening end side of the male screws 5d and 5d in the connecting shaft portions 5c and 5c (FIGS. 2A and 3A) of the head portion shank shaft member 9C of the head 4, the drill head 4 in FIG. As shown representatively by the screw coupling portion 13 (see FIG. 1 (B)) between the head portion shank shaft member 9C and the intermediate portion shank shaft member 9B, the incomplete thread portion 13a of the female and male screws 5a, 5d is removed from the discharge groove. 1 (1C) is formed, the screw ends are completed with a complete screw cross-sectional shape on both sides of the discharge groove 1 (1C), and no gap is formed at the screw ends facing the discharge groove 1. .
[0044]
The intermediate shank shaft member 9B and the head shank shaft member 9C are connected to the connecting shaft portions 5c and 5c, and the intermediate shank shaft member 9B and the base shank shaft member 9A are respectively connected to the connecting cylinder portions 5a and 5a. As the pilot portions having the same length and substantially the same inner and outer diameters, the connecting shaft portions 5c and 5c are smoothly fitted into the connecting tube portions 5a and 5a so that they can be accurately screwed into the concentric state.
[0045]
In such a gun drill, a shank shaft 3 having a length of about 150 to 500 mm is usually used, and a plurality of intermediate shank shaft members 9A having different lengths in such a range are prepared. Keep it. Moreover, although the drill head 4 was illustrated as a cutting head in the said embodiment, the head part shank member 9C is formed in the base end side similarly to the drill head 4 also as a cutting head used for other cutting operations, such as a milling head, for example. Thus, it is recommended to prepare a connecting shaft portion 5c having a male screw 5d and an outer peripheral surface provided with discharge grooves 4c and 1C over its entire length.
[0046]
In this gun drill, first, through-holes 7 are provided concentrically on the shank shaft 3 in substantially the entire axial direction, and this through-hole 7 is used as the coolant supply passage 2. Is easy to manufacture. In addition, this shank shaft 3 is applicable not only to the case where a plurality of shank shaft members 9 are screw-connected to each other as will be described later, but also to the case of a single long shank shaft. It is.
[0047]
Even when the through hole 7 is formed by drilling the central portion of the solid round shaft member in manufacturing, when the through hole 7 is formed concentrically (axial center) of the solid round shaft member, Therefore, the drilling operation can be performed by the relative rotation of the solid round shaft member and the drilling tool. Even if it is a long member exceeding a meter, a through hole which is a coolant supply passage having excellent straightness can be formed, and a deep hole cutting tool with good accuracy can be easily manufactured.
[0048]
Furthermore, since the through-hole 7 is formed concentrically on the shank shaft 3 and this through-hole 7 is used as the coolant supply passage 2, the coolant supply passage 2 can be formed with a large diameter, and the supply capacity of the coolant is improved accordingly. Can be made. Thus, even if the coolant supply passage 2 is formed to have a large diameter, by reducing the cross-sectional area of the coolant discharge groove 1 formed by cutting the outer peripheral wall of the shank shaft 3 as much as possible as described later. The shaft strength can be ensured sufficiently.
[0049]
Then, a part of the outer peripheral wall of the shank shaft 3 is cut away from the through-hole 7, that is, not to communicate with the through-hole 7, so as to cut out the entire region in the substantially axial direction. Therefore, since it is only necessary to cut a part of the shank shaft 3 in the axial direction from the viewpoint of production, the production is easy.
[0050]
Further, by cutting away a part of the outer peripheral wall of the shank shaft 3 while avoiding the through hole 7, a part of the outer peripheral surface 8a of the through hole 7 is exposed at the bottom of the cut part 8, Accordingly, the cut portion 8 is formed by a gap surrounded by the exposed outer peripheral surface 8a of the through hole 7 and the cut end surfaces 8b and 8c obtained by cutting a part of the shank shaft 3, and the cut portion 8 has a large diameter. Since the cross-sectional area of the coolant discharge groove having a V-shaped cross-section passing through the shaft center of the conventional shank shaft is smaller than that of the conventional through-hole 7 formed in Moreover, even if the coolant supply capacity of the coolant supply passage 2 is improved, even if the cross-sectional area of the coolant discharge groove is slightly reduced, the coolant flow rate is rather increased, and the chip discharge capacity can be significantly improved. it can.
[0051]
Further, according to the gun drill of the present embodiment, the shank shaft 3 is composed of the base side shank member 9A and the intermediate portion shank shaft member 9B which is an independent member. By doing so, the shank length can be changed, so that it is possible to set an appropriate shank length according to the drilling depth to be applied using the same base shank shaft member 9A. Accordingly, the equipment cost is greatly reduced as compared with the case of preparing a plurality of types of deep hole cutting tools having different shank lengths in several stages as in the prior art. Further, the wear on the shank side with time, and sudden breakage and deformation on the shank side during use mostly occur in the middle portion of the shank shaft where twisting stress due to cutting load tends to concentrate. In this gun drill, the concentrated portion of the torsional stress is generally the intermediate shank shaft member 9B. Therefore, only the damaged intermediate shank shaft member 9B is replaced with a new one. High base shank member 9A can be used continuously over a long period of time, which can greatly reduce maintenance costs.
[0052]
Furthermore, in the gun drill of the present embodiment, one end side of the intermediate shank shaft member 9B constitutes the connecting shaft portion 5c having the male screw 5d, and the other end side has the connecting tube portion 5a having the female screw 5b, and the base side shank member 9A. And the connecting cylindrical portions 5a and 5a of the intermediate shank shaft member 9B, and the connecting shaft portions 5c and 5c of the intermediate shank shaft member 9B and the head shank member 9C of the drill head 4 are set to the same size and shape. A plurality of intermediate shank shaft members 9B... Are connected in a straight line, or a drill head with respect to a single long shank shaft 3 provided with a driver portion 16 at the base without using the intermediate shank shaft member 9B. 4 can also be directly connected, and by connecting a plurality of intermediate shank shaft members 9B, it is possible to cope with extremely long drilling holes, but conversely to one long shank shaft 3 It can cope with relatively short drilling by direct coupling of Riruheddo 4.
[0053]
On the other hand, when the carbide tip 17 that is the cutting edge of the drill head 4 is worn out or broken, only the drill head 4 needs to be replaced, and the base shank shaft member 9A and the intermediate shank shaft member 9B are continued. It can be used, and only the drill head 4 needs to be replaced by screwing in when changing the setup. Therefore, the work can be easily performed in a short time, and the production efficiency can be improved. Also, switching to other cutting work such as drilling and reaming can be performed. Even in this case, it is only necessary to prepare a corresponding type of cutting head, so that the equipment cost can be reduced and the replacement work can be easily performed in a short time.
[0054]
Further, in the present embodiment, the female screw 5b and the male screw 5d at each screw coupling portion of the intermediate shank shaft member 9B, the base shank member 9A, and the head shank member 9C of the drill head 4 are constituted by square screws. In addition, a high coupling strength can be obtained, and a gap is hardly generated in the threaded portion, so that leakage of coolant from the threaded coupled portion is prevented.
[0055]
Further, as shown in FIG. 4C, the incomplete threaded portions on the end side of the male screw 5d and the open end side of the female screw 5b in each screw engaging portion are formed in the discharge groove 1 (1A, 1B, 1C). Since it is within the formation range, screw ends having a complete cross-sectional shape face both side surfaces of these discharge grooves and no gap is formed, so that a problem that chips are caught in the gap and cannot be discharged smoothly is prevented.
[0056]
In the above-described embodiment, one end of the base shank shaft member 9A and the intermediate shank shaft member 9B is the connection cylinder portion 5a and the female screw 5b, and the other end of the intermediate shank shaft member 9B is the connection shaft portion 5c and the male screw 5d. One end portion of the head shank shaft member 9C is a connecting shaft portion 5c and a male screw 5d. On the other hand, one end portion of the base shank shaft member 9A and the intermediate portion shank shaft member 9B is connected to the connecting shaft portion 5c and the male screw. 5d, the other end of the intermediate shank shaft member 9B is a connecting tube portion 5a and a female screw 5b, and one end of the head portion shank shaft member 9C is a connecting tube portion 5a and a female screw 5b. May be formed. In the description of the embodiment, an example in which the carbide tip 17 that forms a cutting edge is brazed to the drill head 4 is shown. However, the entire cutting head such as the drill head 4 is made of tool steel and the tip is cut. A configuration in which a blade is directly formed or the carbide tip 8 is screwed to the drill head 3 can be employed. Furthermore, the circumferential length L2 of the discharge groove 1 (1A, 1b, 1C) of each member 9A, 9B, 9C is exemplified by a V-shaped cross section having an opening angle of 90 °, but is approximately 90 ° to 130 °. An appropriate opening angle in the range of ° can also be set.
[0057]
【The invention's effect】
According to the first aspect of the present invention, first, a through hole is provided concentrically on the shank shaft in substantially the entire axial direction, and this through hole is used as a coolant supply passage. Easy to manufacture. In addition, this shank axis | shaft is naturally applied also when it consists of one long shank axis | shaft other than the case where several shank shaft members are mutually screw-coupled and formed as mentioned later. .
[0058]
In production, even when the through hole is formed by drilling the central part of the solid round shaft member, the solid circle is used when the through hole is formed concentrically (shaft center) of the solid round shaft member. Drilling work can be performed by the relative rotation of the shaft member and the drilling tool. For this reason, even if the solid round shaft member is a long member exceeding 1.5 meters, coolant supply with excellent linearity is provided. A through hole which is a passage can be formed, and a deep hole cutting tool with good accuracy can be easily manufactured.
[0059]
Furthermore, since a through hole is formed concentrically on the shank shaft and this through hole serves as a coolant supply passage, the coolant supply passage can be formed with a large diameter, and the coolant supply capacity can be improved accordingly. Thus, even if the coolant supply passage is formed to have a large diameter, the shaft strength can be reduced by making the cross-sectional area of the coolant discharge groove formed by cutting a part of the outer peripheral wall of the shank shaft as small as possible. Can be ensured sufficiently.
[0060]
And, avoiding the through hole in a part of the outer peripheral wall of the shank shaft, i.e., cutting the entire region in the substantially axial direction so as not to communicate with the through hole, this cut portion became a discharge groove for coolant and chips, From the viewpoint of production, it is only necessary to cut a part of the shank shaft in the axial direction, so that the production is easy.
[0061]
And also, by cutting to avoid the through hole part of the outer peripheral wall of the shank axis, the bottom of the該切removal portion forms a concentric convex arc face the through hole, therefore,該切dividing section the convex arc Formed by an air gap surrounded by a surface and a cut end face obtained by cutting a part of the shank shaft, and the cut portion is formed outside a through-hole formed in a large diameter. Compared with the cross-sectional area of the coolant discharge groove having a V-shaped cross section passing through the coolant, the cross-sectional area is smaller. However, coupled with the improvement of the coolant supply capacity of the coolant supply passage as described above, the coolant discharge groove is cut off. Even if the area is slightly reduced, the flow rate of the coolant is rather increased, and the chip discharge capacity can be significantly improved. In addition, on the tip side of the cutting head, a plurality of coolant discharge ports are provided in communication with a plurality of coolant supply passages branched from the through holes, and the coolant discharge grooves on the side surfaces of the groove bottom are substantially the shaft of the cutting head. Since it is formed in a V-shaped cross section located at the center, it does not hinder the discharge ability of chips and coolant.
[0062]
According to the second aspect of the present invention, when the cutting head is provided so as to be detachable from the shank shaft, it is necessary to replace either the cutting head or the shank shaft due to wear or chipping. Compared to the one integrated with the shank shaft, it is only necessary to replace the above-mentioned parts that are worn or missing.
[0063]
Furthermore, when switching to other cutting operations such as drilling and reaming, it is possible to easily switch from drilling to reaming by simply replacing this cutting head, while the shank shaft is used continuously. can do.
[0064]
As described above, since the cutting head 4 is connected to the shank shaft 3 by screw connection, the connecting structure between the two can be manufactured easily and inexpensively, and either one at the time of wear or chipping can be produced. The parts can be easily replaced.
[0065]
According to the invention of claim 3, since the shank shaft is composed of a plurality of shank shaft members that are screw-coupled to each other, if a plurality of shank shaft members having different lengths are prepared, the shank shaft members can be exchanged. The shank length can be changed, so that an appropriate shank length can be set according to the drilling depth to be applied without replacing the shank shaft member having the driver portion on the base end side. When wear, breakage, deformation or the like occurs, only the shank shaft member can be replaced and used continuously.
[0066]
According to the invention which concerns on Claim 4, it becomes possible to connect a some shank shaft member as needed, or to connect a cutting head to a shank shaft member, and to perform required cutting.
[0067]
According to the fifth aspect of the present invention, when the screw engaging portions between the shank shaft members or between the shank shaft member and the cutting head are square screws, the coupling strength is increased and the gap is less likely to be generated. Coolant leakage from the joint can be prevented.
[0068]
Further, the incomplete threaded portion on the end side of the male screw and the open end side of the female screw in each thread engaging portion between the shank shaft members or between the shank shaft member and the cutting head does not exist within the formation range of the discharge groove. Since this is in a state, a complete end face shaped screw end faces the cut end face that forms the discharge groove, and no gap is formed, so that it is possible to prevent the occurrence of problems such as chips being caught in the gap and being not smoothly discharged. .
[0069]
According to the invention which concerns on Claim 6, although the discharge groove | channel of a coolant is formed in the part by which a part of outer peripheral wall of the shank axis | shaft was excised, the depth of the radial direction of the part, ie, a shank axis | shaft, is formed. The depth of the cut end face obtained by cutting the outer peripheral wall and the amount of cutting of the outer peripheral wall in the circumferential direction of the shank shaft can be freely set within the above range, whereby the coolant discharge capacity, and therefore the work piece cutting. The discharge capacity of chips generated in the hole can be freely adjusted.
[Brief description of the drawings]
1A and 1B show a gun drill according to an embodiment of the present invention, in which FIG. 1A is a partially omitted front view showing an overall configuration, FIG. 1B is an enlarged view in an imaginary line circle B in FIG. It is an enlarged view in virtual line circle C of (A).
FIG. 2 shows a base shank shaft member used in the gun drill of the same embodiment, (A) is a partially omitted front view showing the entire configuration, (B) is a side view seen from the tip, and (C) is a side view of (A). It is arrow sectional drawing of a CC line.
FIG. 3 shows an intermediate shank shaft member used in the gun drill of the same embodiment, (A) is a partially omitted front view showing the overall configuration, (B) is a side view seen from the tip, and (C) is (A). It is arrow sectional drawing of the CC line.
4A and 4B show a cutting head used in the gun drill of the embodiment, in which FIG. 4A is a partially omitted front view showing the entire configuration, FIG. 4B is a side view seen from the tip, and FIG. 4C is C- in FIG. Sectional drawing of C line, (D) is the side view seen from the base end.
FIG. 5 is a front view of a gun drill showing another embodiment of the present invention.
6A and 6B are a schematic configuration of a conventionally used gun drill system and a cross-sectional view of a gun drill used therefor.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Coolant discharge groove 2 Coolant supply passage 3 Shank shaft 4 Cutting head 7 Through hole 8 Cut portion 9 Shank shaft member 9A Base shank shaft member 9B Intermediate portion shank shaft member 9C Head portion shank shaft member 10 Screw coupling portion 5d Male screw 5b Female thread 13 Screw coupling part 13a Incomplete thread part 15 Discharge port 16 Driver part

Claims (6)

A shank shaft provided with a coolant discharge groove in the outer peripheral portion and provided with a coolant supply passage therein , and a cutting head at the tip of the shank shaft, and a part of the outer peripheral wall from the shank shaft to the cutting head tip there are excised linearly, the cut portion is a deep hole cutting tool that form a discharge groove of the coolant,
A through hole forming the coolant supply passage is provided concentrically with the shank shaft from the base side of the shank shaft to the longitudinal intermediate portion of the cutting head, and the through hole extends from the longitudinal intermediate portion of the cutting head to the tip. A plurality of coolant supply holes branched from the hole are drilled, and a plurality of discharge ports communicating with the coolant supply holes are provided on the tip surface of the cutting head,
The discharge groove is formed so as to avoid the through hole and the coolant supply hole, and the bottom of the groove forms a concentric arc surface concentric with the through hole from the shank shaft to the longitudinal middle portion of the cutting head. longitudinally from the intermediate portion to the tip in a V-shaped groove bottom is positioned on substantially the axis of the cutting head, and have a cutting edge over substantially the entire width of the cross section V-shaped one side to the cutting head tip of A deep hole cutting tool characterized by comprising:   The deep hole cutting tool according to claim 1, wherein the shank shaft is provided with a cutting head detachably attached to a tip portion by screw connection.   The deep hole cutting tool according to claim 1 or 2, wherein the shank shaft is composed of a plurality of shank shaft members, and each of the shank shaft members is detachably coupled to each other. One of the screw coupling portions on both sides of the shank shaft member constitutes a male screw and the other constitutes a female screw, and the screw coupling portion between the shank shaft member and the cutting head has the same size and shape as the screw coupling portion between the shank shaft members. The deep hole cutting tool according to claim 3 , which is set as follows. The screw used for the screw connection is a square screw, and the incomplete screw portions on the end side of the male screw and the open end side of the female screw in the square screw do not exist within the formation range of the coolant discharge groove. The deep hole cutting tool according to any one of claims 2 to 4.   In the coolant discharge groove on the outer periphery of the shank shaft, the depth of the cut surface in the direction orthogonal to the shaft is a ratio of 1/2 to 1/4 of the radius of the shank shaft. The deep hole cutting tool according to any one of claims 1 to 5, wherein the deep hole cutting tool is formed to have a length ratio of 3 to 1/5.

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