JP2001105216A - Stepping rotating cutting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stepping rotating cutting device such as a stepping drill smoothening outflow of chips for preventing chip packing to reduce breakage accidents during processing due to the chip packing. SOLUTION: Steps in a tool radial direction are formed in a groove 13 on an outer circumference of a small radial part 11 of a stepping drill 10 and in a groove 14 of a large radial part 12 to be a subland structure. An outer circumferential rake γ1 of the small radial part 11 is set 0 deg. or more and an outer circumferential rake γ2 of the large radial part 12 is set 0 deg. or less for making a moderate angular difference between both the rakes to prevent chips of the small radial part 12 and of the large radial part 12 from flowing into the groove 14 and 13 sides respectively.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stepped rotary cutting tool capable of reducing breakage during cutting and facilitating re-grinding at the same time. The present invention is also effective for stepped reamers, stepped end mills, etc.
Since the subject is considered to be a stepped drill, the following description will be made by taking a stepped drill as an example.

[0002]

2. Description of the Related Art FIG. 5 shows an overall view of a well-known step drill. The stepped drill 1 is for simultaneously processing a stepped hole, drilling and chamfering a hole edge, and has a large diameter portion 3 connected to the rear of a small diameter portion 2. L ₁ in FIG. 5 is a step length of the small diameter portion 2, alpha ₁ is a step angle. Step angle alpha ₁ is normally set to about 90 ° to 120 °.

[0003]

A stepped drill is, like a general drill, a case in which the material is changed from high-speed steel (high-speed steel) to a cemented carbide in order to increase durability, and in addition, a surface drill is used. More and more cases are provided with a hard coating layer.

[0004] However, a cemented carbide drill using a cemented carbide having a lower toughness than that of high-speed steel often breaks particularly when cutting is performed simultaneously on a small diameter portion and a large diameter portion.

[0005] In addition, a carbide drill, which is more expensive than a high-speed steel drill, is repeatedly used as much as possible in order to reduce tool cost, but the drill having the structure shown in FIG. A so-called grinding sag (a phenomenon in which traces of the grindstone T remain on the outer periphery after polishing and the surface becomes rough as shown in FIG. 6) occurs at the rear end of the small-diameter portion. Occur. Therefore, after the re-polishing, the breakage described above is more likely to occur.

[0006] An object of the present invention is to solve such a problem and improve the service life and performance of a tool, and also to realize easiness of regrinding and the like.

[0007]

In order to solve the above-mentioned problems, the present invention has a small-diameter portion and a large-diameter portion connected to the rear of the small-diameter portion, and each of the small-diameter portion and the large-diameter portion is cut off. In a stepped rotary cutting tool having a blade, a step in the tool rotation direction is formed in the outer peripheral groove of the small diameter portion and the outer peripheral groove of the large diameter portion to form a multi-groove structure, and further, the outer peripheral rake angle γ _{1 of the} small diameter portion and the large diameter portion of the outer peripheral rake angle gamma _2, gamma ₁ is 0 ° or more, gamma ₂ is was made different from each other as in the range of 0 ° or less.

[0008]

[Function] A step drill often breaks during machining because the chip generated at the small diameter part and flowing toward the back of the groove interacts with the chip generated at the tip of the large diameter part. This is due to the fact that the dischargeability is deteriorated, the chip is clogged, and an excessive torque is applied to the drill. The inventor investigated this fact and made two improvements so that chip mutual interference could be effectively prevented.

A first improvement is that the chip discharging groove has a double groove structure. If a step in the radial direction of the tool is generated between the groove of the small diameter part and the groove of the large diameter part in this way, the flow path of the chip generated at the large diameter part and the chip generated at the small diameter part may be separated and the chips may interfere with each other. Less. However, a stepped drill having a double-groove structure already exists, and even with this drill, breakage during processing cannot be sufficiently suppressed. This is only because the effect of preventing chips from interfering with each other is insufficient.

Therefore, as a second measure, the outer rake angles of the small diameter portion and the large diameter portion are set to 0 ° or more for the former and 0 ° or less for the latter, so that both rake angles are differentiated. As a result, chips in the small diameter portion are guided toward the center of the tool, and chips in the large diameter portion are guided toward the outer peripheral side of the tool. Interference has been effectively prevented.

In addition, in the case of a multi-groove structure, the inner end of the cutting edge at the tip of the large-diameter portion extends from the land portion of the small-diameter portion and enters the tool center side from the margin portion of the small-diameter portion,
Since the entry portion serves as an ineffective region of the cutting edge, the inner edge of the cutting edge of the large diameter portion does not require accuracy. Further, regeneration of the margin behind the small-diameter portion is not required, which facilitates repolishing. Further, even if the surface property of the land portion behind the small-diameter portion newly cut out by re-polishing is poor, the portion is not related to the processing accuracy, so that the reproducibility of the tool performance is excellent. Furthermore, even if traces of the grindstone remain on the newly ground lands, the margin of the small-diameter portion is kept in a healthy state, so that a decrease in the rigidity of the tool due to re-polishing can be suppressed to a small extent.

The effects of facilitating re-polishing, improving reproducibility of tool performance, and maintaining tool rigidity after re-polishing are due to the multi-groove structure, and cannot be said to be unique effects of the present invention. By obtaining these effects together, the tool becomes better.

[0013]

1 and 3 show an embodiment of a tool according to the present invention. The illustrated tool exemplifies a step burnishing drill.

FIG. 1 shows a drill with a straight groove, and FIG. 3 shows a drill with a torsion groove. Both drills have a large-diameter portion 12 provided continuously behind a small-diameter portion 11. These drills 10
Is a double groove structure, the groove 13 of the small diameter portion and the groove 1 of the large diameter portion.
A step in the tool rotation direction is generated between the four.

As shown in FIG. 2, the small diameter portion 11 of the drill shown in FIG. 1 has a groove 13, a cutting edge 15 including a chisel blade, and a flank 1
6. The land portion 18 including the margin portion 17 is point-symmetric with respect to the center of rotation, and the large-diameter portion 12 is defined with respect to the groove 14, the cutting edge 19, the flank 20, and the land portion 21 with respect to the center of rotation. The structures are provided in a point symmetric state.

The drill shown in FIG. 3 has a similar structure, although an end view is omitted.

The drill 10 of FIGS. 1 and 3 differs only in that the grooves are straight or twisted. FIG.
Reference numeral 22 denotes an oil hole provided as needed.
In some cases, this oil hole is also provided in the drill.

In both drills, the large diameter portion 12 is used for chamfering the edge of the hole formed in the small diameter portion 11. Therefore,
Although the margin portion of the large-diameter portion 12 is omitted, a margin portion for burnishing is also provided in the large-diameter portion for processing a stepped hole.

The end of the margin portion 17 of the small diameter portion extends to near the end of the groove 14 of the large diameter portion.
The groove 14 of the large diameter portion is formed at a position along the tool rotation direction 7 behind.

Further, here, the outer peripheral rake angle gamma ₁ of the groove 13 shown in FIG. 4 5 °, the outer peripheral rake angle gamma ₂ in grooves 14 -1
It is set to 0 °. For this reason, the chips generated by the cutting edge 15 flow toward the groove bottom side of the groove 13 due to the guiding force of the groove surface of the groove 13, while the chip generated by the cutting edge 19 flows to the outer peripheral side of the groove 14. . Therefore, the chips do not interfere with each other, and the chips flow out smoothly. Therefore, chip clogging does not occur, and breakage of the drill due to chip clogging is reduced.

The outer peripheral rake angle γ ₁ of the small diameter portion 11 is
In order to prevent chips inside the tool from flowing to the outer circumference of the tool,
Further, in order to prevent chips in the groove 14 from flowing toward the center of the tool, γ ₁ has a lower limit value and γ ₂ has an upper limit value of 0 ° for the outer peripheral rake angle γ ₂ of the large diameter portion 12. Angular difference between the gamma ₁ and gamma ₂ is, 5 ° to 30 °, more preferably about 1
It is good to be about 0 ° to 20 °. If the angle difference is too small, the effect of preventing chips from interfering will be weakened, while if the angle difference is too large, the groove width of the groove 13 will be insufficient, and the sharpness of the cutting edge 19 will tend to decrease.

Although the cutting edge 19 may be a straight blade, FIG.
In the case of using a convex curved blade as shown in (1), the bite against the work material hits the point, the cutting resistance is reduced, and the effect of preventing chatter is also produced.

In addition, the step angle α of the large diameter portion 12
₁ selects a value that matches the shape of the machined hole. Its value is 30
° or 180 °.

Next, in the illustrated drill having the double groove structure, the inner end of the cutting edge 19 enters the tool center side of the margin portion 17. Although the penetration amount is not so large, the penetration portion becomes an ineffective area not involved in cutting, so that even if the inner end of the cutting edge 19 is poorly finished, the cutting performance is not affected at all. Further, there is no need to newly cut out the margin portion 17 at the time of re-polishing, so that re-polishing becomes easy.

Further, since the margin portion 17 is not shaved during re-polishing, the rigidity of the tool due to the re-polishing is hardly reduced.

The present invention is not limited to drills, and is also effective when used in stepped reamers, stepped end mills, and the like.

[0027]

As described above, the tool of the present invention
In addition to the multi-groove structure, the difference in the outer rake angle between the small diameter part and the large diameter part ensures that the small diameter part and the large diameter part are prevented from interfering with each other, effectively preventing chip clogging. As a result, tool breakage is reduced and tool life is improved.

Further, the effects of the multi-groove structure, that is, the effect of facilitating re-polishing, improving the reproducibility of tool performance by re-polishing, and maintaining the rigidity after re-polishing are also obtained. It is also advantageous in terms of shortening the polishing time.

[Brief description of the drawings]

FIG. 1 is a side view showing an embodiment of a tool according to the present invention.

FIG. 2 is a front view of the same tool.

FIG. 3 is a side view of another embodiment.

FIG. 4 is an enlarged cross-sectional view taken along line XX of FIGS. 1 and 3;

FIG. 5 is a side view of a conventional step drill.

FIG. 6 is an explanatory view of sagging by re-polishing.

[Explanation of symbols]

10 stepped burnishing drill 11 small diameter portion 12 large diameter portion 13, 14 groove 15, 19 cutting edges 16, 20 flank 17 margin 18, 21, the land portion 22 oil hole gamma _1, gamma ₂ outer peripheral rake angle

Claims (1)

[Claims] 1. A stepped rotary cutting tool having a small-diameter portion and a large-diameter portion connected to the rear of the small-diameter portion, wherein each of the small-diameter portion and the large-diameter portion has a cutting edge. The groove on the outer circumference of the large diameter part has a step in the tool rotation direction to form a double groove structure.Furthermore, the outer rake angle γ _{1 of the} smaller diameter part and the outer rake angle γ ₂ of the large diameter part, γ ₁ is 0 ° or more , And γ ₂ are different from each other so as to be within a range of 0 ° or less.