阅读说明：本技术 切削工具 (Cutting tool ) 是由 加藤巽 大塚润 井田雄大 于 2021-05-28 设计创作，主要内容包括：本发明提供一种能够牢固地固定切削刀片的切削工具。该切削工具能够安装具有用于固定的穿孔的更换式的切削刀片,其具备主体部、杠杆、销和螺钉,主体部具有载置切削刀片的载置面、与切削刀片的至少一个侧面相接的侧壁、杠杆收容孔、销收容孔和螺钉收容孔,通过拧紧螺钉,螺钉推压销的后端部,销的后端部被螺钉推压,由此其前端部推压杠杆,杠杆具有由平行于基准轴的线段构成的凹面,凹面被销的前端部推压,由此杠杆的向已载置的切削刀片的穿孔突出的头部推压穿孔的内壁,从而将切削刀片压于载置面和侧壁而进行固定。(The invention provides a cutting tool capable of firmly fixing a cutting blade. The cutting tool is capable of mounting a replaceable cutting insert having a through hole for fixing, and comprises a body having a mounting surface on which the cutting insert is mounted, a side wall in contact with at least one side surface of the cutting insert, a lever receiving hole, a pin receiving hole, and a screw receiving hole.)

1. A cutting tool capable of mounting a replaceable cutting insert having a through hole for fixation, wherein,

the cutting tool comprises a main body part, a lever, a pin and a screw,

the main body portion has:

a mounting surface on which the cutting insert is mounted such that a central axis of the through hole is perpendicular to the mounting surface;

a side wall that comes into contact with at least one side surface of the cutting insert when the cutting insert is placed on the placement surface;

a lever receiving hole that receives a part of the lever and is continuous with the through hole when the cutting blade is placed on the placement surface;

a pin receiving hole receiving a portion of the pin and communicating with a side surface of the lever receiving hole; and

a screw receiving hole that receives at least a part of the screw, at least a part of the screw receiving hole being provided with an internal thread portion that is screwed to an external thread portion of the screw, and the screw receiving hole being communicated with the pin receiving hole,

by tightening the screw, the screw pushes the rear end portion of the pin,

the rear end portion of the pin is pressed by the screw, whereby the front end portion thereof presses the lever,

the lever has a concave surface formed by a line segment parallel to a reference axis, and the concave surface is pressed by the tip portion of the pin, whereby a head portion of the lever projecting toward the hole of the mounted cutting blade presses an inner wall of the hole, and the cutting blade is pressed against the mounting surface and the side wall to be fixed.

2. The cutting tool of claim 1,

the head side of the reference shaft is inclined with respect to a central axis of the lever in a direction away from the pin.

3. The cutting tool of claim 2,

the tip end portion side of the center axis of the pin is inclined in a direction away from the head portion with respect to a horizontal axis orthogonal to a vertical axis of the lever housing hole.

4. The cutting tool according to any one of claims 1 to 3,

the lever has a convex portion between the head portion and the concave surface, and the convex portion protrudes toward a side opposite to a side where the concave surface is provided with respect to a center axis of the lever.

5. The cutting tool according to any one of claims 1 to 4,

in the lever, a notch portion having a width larger than a diameter of the tip portion of the pin is provided from a concave portion provided with the concave surface to a bottom surface of the lever.

Technical Field

The present invention relates to a cutting tool.

Background

There is known a technique of fixing a replaceable cutting insert to a cutting tool body by a lever (lever) provided inside (for example, see patent document 1). According to patent document 1, an inclined surface is provided in a through hole of a cutting insert, and a protruding portion provided on a lever is pressed against the inclined surface, thereby generating a force that draws the cutting insert into a mounting surface of a cutting tool body.

Patent document

Patent document 1: japanese Kokai publication Hei-2004-538163

Disclosure of Invention

In order to improve the use efficiency of the cutting insert, there is a use method in which cutting edges are provided at ridge lines on both surfaces of the cutting insert, and if one surface side reaches the use limit, the other surface side is used in a reversed manner. The cutting insert having such a usage mode generally has a through hole having a cylindrical surface.

However, if the force for pulling the cutting insert into the mounting surface of the cutting tool body by the lever is to be properly exerted on the through hole of the cylindrical surface, the lever needs to be tilted accurately according to the design. However, it is difficult to stabilize the contact point of the pin (plunger) pressing the lever and the lever at one point, which causes the falling direction of the lever to be inconsistent every time the fixing work is performed, and it is conceivable that an appropriate pull-in force cannot be obtained as a result. That is, the cutting insert may not be firmly fixed to the cutting tool.

The present invention has been made to solve the above problems, and provides a cutting tool capable of firmly fixing a cutting insert.

A cutting tool according to one aspect of the present invention is a cutting tool to which an exchangeable cutting insert having a through hole for fixation can be attached, the cutting tool including a body portion, a lever, a pin, and a screw, the body portion including: a mounting surface on which a cutting blade is mounted such that a center axis of a through hole is perpendicular to the mounting surface, a side wall, a lever receiving hole, a pin receiving hole, and a screw receiving hole; the side wall is in contact with at least one side surface of the cutting insert when the cutting insert is placed on the placement surface; the lever receiving hole receives a part of the lever and is continuous with the through hole when the cutting blade is placed on the placing surface; the pin receiving hole receives a part of the pin and is communicated with the side surface of the lever receiving hole; the screw receiving hole receives at least a part of the screw, the screw receiving hole is provided at least at a part thereof with an internal thread portion to be screwed with an external thread portion of the screw, the screw receiving hole communicates with the pin receiving hole, the screw presses a rear end portion of the pin by tightening the screw, the rear end portion of the pin is pressed by the screw, thereby a front end portion thereof presses the lever, the lever has a concave surface formed by a line segment parallel to the reference axis, the concave surface is pressed by the front end portion of the pin, so that a head portion of the lever protruding toward a through hole of the mounted cutting blade presses an inner wall of the through hole, thereby the cutting blade is fixed by pressing the mounting surface and the side wall.

As described above, by bringing the tip end portion of the pin into contact with the concave surface formed by the line segment parallel to the reference axis, the lever is stably tilted in the predetermined direction even if the contact point is shifted in the line segment direction. That is, the cutting insert can be firmly pressed against the side wall and the mounting surface, and can be firmly fixed.

In the cutting tool, the head portion side of the reference shaft may be inclined in a direction away from the pin with respect to the central axis of the lever. With such an axial relationship, the pressing force of the pin can be more effectively converted into a force that draws the cutting insert into the mounting surface of the cutting tool body. In this case, the front end side of the center axis of the pin may be inclined in a direction away from the head portion with respect to a horizontal axis perpendicular to the vertical axis of the lever housing hole. Further, by adopting such an axial relationship, the ratio of the downward component of the force pressing the lever can be increased, and the lever is less likely to fall off.

In the cutting tool, the lever may have a convex portion between the head portion and the concave surface, the convex portion protruding toward a side opposite to a side where the concave surface is provided with respect to a center axis of the lever. If such a projection is provided, the projection is stabilized as a fulcrum of the lever that functions as a pry bar, and the tilting direction of the lever is further stabilized.

In the cutting tool, the lever may be provided with a notch portion extending from the concave portion provided with the concave surface to a bottom surface of the lever, and the notch portion may have a width larger than a diameter of the tip end portion of the pin. If such a notch portion is provided in advance, the lever can be easily pulled out from the lever receiving hole even if the pin is not entirely retracted into the pin receiving hole. That is, maintenance work of the cutting tool is easily performed.

According to the present invention, a cutting tool capable of firmly fixing a cutting insert can be provided.

Drawings

Fig. 1 is an overall perspective view of a cutting tool according to the present embodiment.

Fig. 2 is an exploded perspective view showing main elements of the head.

Fig. 3 is a partial cross-sectional view of the head.

Fig. 4 is a perspective view of the lever.

Fig. 5 is a perspective view of the pin.

Fig. 6 is a perspective view of the screw.

Fig. 7 is a partial sectional view showing a state before fixing using a lever.

Fig. 8 is a partial sectional view showing a state after fixing using a lever.

Fig. 9 is a partial sectional view showing a state where the lever is pulled out.

Detailed Description

Embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same or similar components are denoted by the same reference numerals.

Fig. 1 is an overall perspective view of a cutting tool 100 according to the present embodiment. The cutting tool 100 in the present embodiment is a cutting tool for a lathe. The body 110 has a head 111 to which the cutting insert 200 is mounted and a shank 112 which is a portion to be fixed to a shank of a chuck of a lathe.

The head 111 has a concave mount portion to be able to receive and mount the cutting insert 200. The mounting portion is mainly formed by a mounting surface 113 on which the cutting insert 200 is mounted and two side walls 114 provided on the shank portion 112 side. A part of the lever 130 protrudes from the vicinity of the center of the placement surface 113 so as to be able to tilt.

The cutting insert 200 is, for example, a replaceable tip insert formed in a diamond shape as illustrated. The cutting insert 200 according to the present embodiment has cutting edges at the ridge line on the upper surface side and the ridge line on the lower surface side, respectively. Therefore, if the cutting ability of one cutting edge is reduced to reach the use limit, the user can use the other cutting edge by turning over the cutting insert 200 and remounting it. Further, if the other cutting edge also reaches the use limit, the cutting insert 200 can be removed from the cutting tool 100 and replaced with a new cutting insert 200. The cutting insert may have cutting edges on both ridge lines on the upper surface side and the lower surface side. In such a cutting insert, the upper surface side is available for use 2 times, and the lower surface side is also available for use 2 times.

The cutting insert 200 has a through hole 210, two abutment surfaces 211, and a bottom surface 212, the through hole 210 vertically penetrating through the vicinity of the central portion, the two abutment surfaces 211 being side surfaces that abut against the side walls 114 when fixed, and the bottom surface 212 abutting against the mounting surface 113. If the protruding portion of the lever 130 is received in the through hole 210 and placed on the placement surface 113, the center axis of the through hole 210 is perpendicular to the placement surface 113. That is, even if the cutting insert 200 is placed on the placement surface 113 with the opposite surface as the bottom surface 212 by turning it over, the center axis of the through hole 210 is perpendicular to the placement surface 113. As will be described in detail later, if the lever 130 is tilted, the abutment surface 211 is pressed against the side wall 114, the bottom surface 212 is pressed against the mounting surface 113, and the cutting insert 200 is firmly fixed to the cutting tool 100. The portion of the cutting insert 200 abutting the side wall 114 may be a portion of the side surface. For example, if the contact surface 211 is pressed against the ridge line of the upper portion of the sidewall 114, the two are in line contact. When the side wall 114 or the contact surface 211 is provided with a convex portion, both are in point contact.

In the present embodiment, the cutting tool 100 on which the rhombic cutting insert 200 is mounted is described, but the cutting tool may be a cutting tool on which a cutting insert having another shape such as a triangular shape, a rectangular shape, or a circular shape can be mounted. In either case, the cutting insert has the same through hole located near the central portion, and the abutment surface and the bottom surface that are pressed against the cutting tool. The cutting tool may have a mounting surface and a side wall corresponding thereto. One sidewall, or three or more sidewalls, may be in contact with the contact surface.

Fig. 2 is an exploded perspective view showing main elements of the head 111. The head 111 is assembled with a lever 130, a pin 140, and a screw 150. Therefore, the head 111 is provided with a lever receiving hole 115, and the lever receiving hole 115 is continuous with the through hole 210 of the cutting blade 200 when the cutting blade 200 is placed on the placement surface 113. The lever receiving hole 115 receives a portion of the lever 130.

Further, a pin introduction hole 116 is provided at the tip end portion of the head portion 111, and the pin introduction hole 116 is used to accommodate a pin 140 in a pin accommodation hole described later. The pin 140 is assembled into the head 111 through the pin introduction hole 116. A screw receiving hole 117 for receiving the screw 150 is provided in a side portion of the head 111. A female screw portion is provided on the inner periphery of the screw receiving hole 117, and the screw 150 is assembled into the head 111 while being screwed into the female screw portion.

Fig. 3 is a partial sectional view of the head 111. Specifically, the cutting insert 200 is a sectional view of the head 111, and the lever 130, the pin 140, and the screw 150 are shown as being assembled into the head 111 without being cut.

The lever accommodation hole 115 is a bottomed hole having a cylindrical side surface. As described above, the lever receiving hole 115 is continuous with the through hole 210 of the mounted cutting insert 200, and the entire lever 130 is received in the inside thereof. More specifically, when the lever 130 is assembled into the lever receiving hole 115, the head portion 131 protrudes from the lever receiving hole 115, and the through hole 210 receives the protruding head portion 131. The lever receiving hole 115 has an inner space to the extent that the lever 130 can be tilted when the cutting insert 200 is fixed.

The pin introduction hole 116 communicates with a side surface of the lever accommodation hole 115 inside the head 111, and a pin accommodation hole 118 is provided on an extension line of the pin introduction hole 116. The pin 140 introduced from the pin introduction hole 116 is fitted into the pin accommodation hole 118. Although the pin introduction hole 116 and the pin receiving hole 118 are interrupted by the lever receiving hole 115, they are actually formed as uninterrupted holes. In addition, as will be described later, the tip end portion of the pin 140 is formed slightly larger than the trunk portion, and therefore, the pin introduction hole 116 through which the tip end portion passes has a larger inner diameter than the pin accommodation hole 118 that does not accommodate the tip end portion. The inner diameter of the pin receiving hole 118 is set slightly larger than the diameter of the trunk portion so that the trunk portion of the pin 140 can slide.

The screw receiving hole 117 communicates with a rear end of the pin receiving hole 118, which is an opposite side of a front end of the pin receiving hole 118 communicating with the lever receiving hole 115. As described above, the screw receiving hole 117 has the female screw portion formed on the inner peripheral surface thereof, and the screw 150 is screwed into the female screw portion by being rotated, and finally comes into contact with the rear end portion of the pin 140 protruding into the screw receiving hole 117. Fig. 3 shows a state where the screw 150 is in contact with the rear end of the pin 140.

Fig. 4 is a perspective view of the lever 130. The lever 130 includes three portions, i.e., a head portion 131, a body portion 132, and a flange portion 133. As described above, the head 131 enters the inside of the through hole 210 of the cutting insert 200, and functions as a pressing portion that presses the inner wall of the through hole 210.

The body 132 is formed in a cylindrical shape slightly thicker than the head 131, and a large recess 134 is provided near the center thereof. The recess 134 has a concave surface 135 provided as a cylindrical surface in its inner surface. The concave surface 135 will be described in detail later. Main body 132 has a cutout 137 partially cut out by width W from below recess 134 to bottom surface 136 of main body 132.

The flange 133 is an annular flange formed between the head 131 and the body 132 and protruding further than the cylindrical surface of the body 132. As will be described later, the flange 133 comes into contact with the inner peripheral surface of the lever receiving hole 115 and functions as a fulcrum of the lever 130 functioning as a crow bar.

Fig. 5 is a perspective view of the pin 140. The pin 140 has a rear end portion 141 pressed by the screw 150, a front end portion 142 pressing the lever 130, and a body portion 143 as an intermediate portion thereof. The rear end portion 141 is formed in a conical shape or a hemispherical shape to easily receive the pressing force of the screw 150. As described above, the rear end portion 141 is disposed to protrude from the screw receiving hole 117.

The distal end portion 142 is formed in a hemispherical shape as a whole having a diameter R larger than the diameter of the body portion 143. The front end portion 142 is inserted and arranged inside the concave portion 134 such that a part of the hemispherical portion is in contact with the concave surface 135 of the lever 130. The body portion 143 is accommodated in the pin accommodating hole 118, and slides in the direction of the lever 130 if the rear end portion 141 is pressed.

Fig. 6 is a perspective view of the screw 150. The screw 150 has a wrench hole 151, an external thread portion 152, an engagement surface 153, and a protrusion 154. The wrench hole 151 is provided in an end surface of the screw 150, and the entire screw 150 advances and retreats inside the screw receiving hole 117 by inserting a wrench and rotating. The male screw portion 152 is screwed to a female screw portion provided in the screw receiving hole 117. The engaging surface 153 is a surface of a conical portion continuous from one end of the male screw portion 152. The engagement surface 153 functions to be in contact with the rear end portion 141 of the pin 140 and to transmit the tightening force of the screw 150 to the pin 140. The projection 154 functions to prevent the pin 140 from entering the screw receiving hole 117 too much when the screw 150 is retracted and the engagement surface 153 is separated from the rear end 141 of the pin 140.

Fig. 7 is a partial sectional view showing a state before the cutting insert 200 is fixed using the lever 130. More specifically, it is a diagram showing a state in which the user mounts the cutting insert 200 on the mounting surface 113 and then prepares to tighten the screw 150. In fig. 7, the lever 130 and the pin 140 are also shown in cross section, unlike in fig. 3. L is₁A central axis, P, of the lever 130 formed in a cylindrical shape as a whole₁Is the central axis of the pin 140 which is also formed in a cylindrical shape as a whole. That is, fig. 7 is a sectional view including the central axes of the lever 130 and the pin 140. In fig. 7, hatching (hashing) representing a cross section is omitted for easy understanding of the arrangement relationship between elements.

Reference axis L₂The concave surface 135 is a reference axis of the concave surface 135 illustrated by cross hatching (cross hatching), and the concave surface 135 is formed with the reference axis L₂A portion of a cylindrical surface that is the central axis. In other words, the concave surface 135 and the reference axis L₂Equidistant from the reference axis L₂A set of parallel line segments. If the rear end 141 of the pin 140 is pushed by the screw 150, the front end 142 of the pin 140 comes into contact at any position of the concave surface 135.

If the contact point is not a cylindrical surface such as the concave surface 135 but a three-dimensional curved surface such as a spherical surface whose normal vector changes, the direction of action of the pressing force is deviated when the contact point is deviated from the predetermined position due to the influence of the gap between the body portion 143 of the pin 140 and the pin receiving hole 118. That is, the lever 130 does not fall in a predetermined direction. Thus, the force for drawing the cutting insert 200 into the mounting surface 113 cannot be appropriately exerted, and the cutting insert 200 may be easily removed.

On the other hand, if the concave surface 135 is formed as a part of such a cylindrical surface, the contact point with the pin 140 is directed toward the line segment on the concave surface 135 (the reference axis L)₂Parallel direction), the lever 130 is also stably tilted toward a predetermined fixed direction. Further, during the tilting of the lever 130, since the contact point moves along the line segment, the deviation of the tilting direction is greatly suppressed. Therefore, the force drawing the cutting insert 200 into the mounting surface 113 can be made to act as designed, and the cutting insert 200 can be firmly fixed to the cutting tool 100.

The height d of the concave surface 135 is defined as a range in which the front end 142 of the pin 140 can be in contact. For example, as described above, the size of the gap between the body portion 143 of the pin 140 and the pin receiving hole 118 and the movement distance of the contact point with the falling of the lever 130 are defined. In the present embodiment, the concave surface 135 is formed as a part of a cylindrical surface, but the surface structure for achieving such an effect is not limited to this. For example, the reference axis L may be₂Of the elongated planar surface. That is, any concave surface may be used as long as it is formed of a line segment parallel to the reference axis L2.

When the concave surface 135 is pressed by the tip end portion 142 of the pin 140, the lever 130 functions as a lever having a contact point between the flange portion 133 and the lever receiving hole 115 as a fulcrum. Since the flange 133 protruding into the lever accommodation hole 115 is used as a fulcrum in this way, the position of the fulcrum as a lever is stabilized, and the lever 130 is more stably tilted in a predetermined fixing direction. The projection acting as the fulcrum may not be a flange around the entire circumference of the lever 130, but may be a flange onlyIs relative to the central axis L of the lever 130₁But a convex portion protruding to the side opposite to the side where the concave surface 135 is provided.

Reference axis L₂With respect to the central axis L of the lever on the head 131 side₁But topples away from the pin 140. In other words, the reference axis L₂So as to be closer to the head 131 side than the position where the concave surface 135 is provided and the center axis L₁The manner of the intersection is oblique. By tilting the reference axis L in this way₂The normal line of the concave surface 135 at the contact point can be directed upward rather than horizontally, and thus the pressing force of the pin 140 can be converted into a force that draws the cutting insert 200 into the mounting surface 113 more effectively.

Furthermore, the center axis P of the pin 140₁With respect to a horizontal axis L orthogonal to a vertical axis of the lever accommodation hole 115 on the side of the tip end portion 142₃But is inclined in a direction away from the head 131. By thus inclining the center axis P₁The ratio of the downward component of the force pressing the lever 130 can be increased, so that the lever 130 is not easily detached. In addition, since the upward component of the pressing force of the screw 150 received by the rear end portion 141 of the pin 140 is increased by such inclination, the downward component of the force of the pin 140 pressing the lever 130 can be more reliably secured.

Fig. 8 is a partial sectional view showing a state where the cutting insert 200 is fixed using the lever 130. More specifically, it is a diagram of a state after the user has tightened the screw 150 in the state of fig. 7. However, unlike fig. 7, fig. 8 shows a cross section in hatched lines. Further, the direction of the force is shown by white arrows.

When the screw 150 is tightened, the engagement surface 153 of the screw 150 presses the rear end portion 141 of the pin 140. The front end 142 of the pin 140 receives this pressing force, and presses the concave surface 135 of the lever 130. Then, the lever 130 is inclined with a contact point of the tip end portion 142 of the pin 140 and the concave surface 135 as a point of force and a contact point of the lever accommodation hole 115 and the flange portion 133 as a fulcrum, and the head portion 131 contacts the inner wall 213 of the through hole 210. The contact point between the head 131 and the inner wall 213 functions as a point of action, and the force thereof functions as a pressing force that presses the bottom surface 212 of the cutting insert 200 against the mounting surface 113 and presses the abutment surface 211 against the side wall 114. By this pressing force, the cutting insert 200 is firmly fixed to the cutting tool 100.

The cutting tool 100 may be replaced with the lever 130, pin 140, screw 150 as desired. Fig. 9 is a partial sectional view showing a state where the lever 130 is pulled out. To pull out the lever 130, first, the screw 150 is removed from the screw receiving hole 117, and then the pin 140 is slid in the direction of the screw receiving hole 117 and retracted.

As described above, the lever 130 is provided with the notch 137, and the width W is set to be larger than the diameter R of the tip end portion 142 of the pin 140. Therefore, the tip end portion 142 of the pin 140 is inserted into the notch 137, whereby the pin 140 can be pulled upward. With this configuration, the lever 130 can be easily pulled out from the lever receiving hole 115 without retracting the entire pin 140 to the pin receiving hole 118. That is, maintenance work of the cutting tool 100 is easily performed. Further, the lever receiving hole 115 is miniaturized, and the head 111 is miniaturized.

In the present embodiment described above, a case where the through hole for fixation provided in the cutting insert 200 is the through hole 210 penetrating the upper surface and the lower surface is described. However, in the fixing structure using the lever described above, the above-described effects can be achieved if the inner surface of the through hole of the cutting insert is a vertical surface. That is, the through hole of the cutting insert may be a bottomed hole instead of a through hole. For example, the cutting insert may have a bottomed through hole provided from the lower surface without penetrating the upper surface, and cutting edges may be provided at two ridge lines on the upper surface side. When the cutting edge provided on one ridge line reaches the limit of use, the cutting insert is reattached by releasing the lever and rotating it 180 degrees around the center axis of the through hole, so that the cutting edge provided on the other ridge line can be used.

Description of the symbols

100 … cutting tool, 110 … body portion, 111 … head portion, 112 … shank portion, 113 … placing surface, 114 … side wall, 115 … lever receiving hole, 116 … pin introducing hole, 117 … screw receiving hole, 118 … pin receiving hole, 130 … lever, 131 … head portion, 132 … body portion, 133 … flange portion, 134 … recess portion, 135 … concave surface, 136 … bottom surface, 137 … notch portion, 140 … pin, 141 … rear end portion, 142 … front end portion, 143 … trunk portion, 150 … screw, 151 … hand hole, 152 … male screw portion, 153 trigger 153 … engaging surface, 154 … protrusion, 200 … cutting blade 210, 210 … through hole, 211 … abutting surface, 212 … bottom surface, 213 … inner wall.