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JPS60221208A - Very hard drill and method of strengthening cutting edge thereof - Google Patents

Very hard drill and method of strengthening cutting edge thereof

Info

Publication number
JPS60221208A
JPS60221208A JP7688884A JP7688884A JPS60221208A JP S60221208 A JPS60221208 A JP S60221208A JP 7688884 A JP7688884 A JP 7688884A JP 7688884 A JP7688884 A JP 7688884A JP S60221208 A JPS60221208 A JP S60221208A
Authority
JP
Japan
Prior art keywords
drill
chamfer
cutting edge
rake face
flank
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
JP7688884A
Other languages
Japanese (ja)
Other versions
JPH0134727B2 (en
Inventor
Susumu Mori
進 森
Hisao Oka
久雄 岡
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Sumitomo Electric Industries Ltd
Original Assignee
Sumitomo Electric Industries Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Sumitomo Electric Industries Ltd filed Critical Sumitomo Electric Industries Ltd
Priority to JP7688884A priority Critical patent/JPS60221208A/en
Publication of JPS60221208A publication Critical patent/JPS60221208A/en
Publication of JPH0134727B2 publication Critical patent/JPH0134727B2/ja
Granted legal-status Critical Current

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23BTURNING; BORING
    • B23B51/00Tools for drilling machines
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23BTURNING; BORING
    • B23B2251/00Details of tools for drilling machines
    • B23B2251/12Cross sectional views of the cutting edges
    • B23B2251/125Rounded cutting edges

Landscapes

  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Drilling Tools (AREA)
  • Finish Polishing, Edge Sharpening, And Grinding By Specific Grinding Devices (AREA)

Abstract

PURPOSE:To strengthen the cutting edge of a very hard drill, by improving the form of the chamfered surface of the cutting portion of the drill. CONSTITUTION:A very hard drill is provided with a chamfered surface 13 so as to remove the acute-angle edge of the drill. The chamfered surface 13 is located at the oblique intersection of the rake face 11 and relief face 12 of the drill. A dimension (a) at the chamfered surface 13 and the rake face 11 is made larger than a dimension (b) at the chamfered surface 13 and the relief face 12, so that the angle of the cutting edge of the drill is kept from being made extremely large or blunt. The cutting sharpness of the drill is thus precluded from decreasing. The chamfered surface 13 is a convex arc-shaped surface slowly curving as a whole and extends with a small roundness at each of both the side edges to the rake face 11 and the relief face 12. As a result, the cutting performance of the drill is improved.

Description

【発明の詳細な説明】 (イ) 産業上の利用分野 本発明は、主として金属加工に使用する超硬ドリル、詳
しくは、刃先強化のため]こ切刃部に付すチャンファ(
面取り面)の形状に工夫を凝らした超硬ドリルとそのチ
ャンファ加工を容易かつ正確に行うことのできる刃先強
化法1こ関する。
DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to a carbide drill mainly used for metal processing, and more particularly, to a chamfer (for strengthening the cutting edge) attached to the cutting edge.
This invention relates to a carbide drill with a specially designed chamfered surface and a method for strengthening the cutting edge of the drill for easily and accurately chamfering the drill.

(ロ) 従来技術とその間額点 超硬合金を切刃の材料とした超硬ドリルは、穿孔作業の
高能率化を可能にする反面、抗折力の低さに起因する切
刃の欠けを生じ易い。そこで、−般Iこは超硬合金のも
ろさを補うため、すくい面とこのチャンファは、切刃全
域に渡って付されるが、従来のそれは、第1図乃至第3
図1こ示すように、すくい面1と逃げ面2の斜交部に、
基準線P(この基準線は前切刃の場合回転軸と平行)に
対する頌斜絢θが10〜45 の範囲にあり、かつ、す
くい面に占める設置中aが0.03〜0.3 mm程度
の平担な面3やa寸と同程度の曲率半径をもってすくい
面と逃げ面に連なる丸味のある面とされていたため、ド
リルにおいては安定した性能の確保が困難であった。
(b) Conventional technology and the gap between carbide drills whose cutting blades are made of cemented carbide, while making it possible to increase the efficiency of drilling operations, they do not suffer from chipping of the cutting blades due to their low transverse rupture strength. Easy to occur. Therefore, in order to compensate for the brittleness of cemented carbide, the rake face and this chamfer are applied over the entire cutting edge.
As shown in Figure 1, at the diagonal intersection of rake face 1 and flank face 2,
The diagonal depth θ with respect to the reference line P (this reference line is parallel to the rotational axis in the case of the front cutting edge) is in the range of 10 to 45, and the installation a occupying the rake face is 0.03 to 0.3 mm. It was difficult to ensure stable performance in drills because it was considered to be a rounded surface connected to the rake face and flank face with a radius of curvature similar to the flat surface 3 or dimension a.

即ち、第4図の(a) 、 tb)tこ超硬旋削工具に
よる面取りの角度、大きさを変えての靭性、耐摩耗性の
変化を示す。同図の数値は以下のテスト条件でめられた
ものである。
That is, FIG. 4 (a), tb) and t show changes in toughness and wear resistance by changing the angle and size of chamfering with a carbide turning tool. The numerical values in the figure were determined under the following test conditions.

0耐摩耗性 被削材 : SCM435 (I(s30)工 具 :
 FNIIR−44A、チップ5NG432(3) 材種17’12A 切削条件:■(切削速度)−170m/m1nf(送り
) =0.36mm/ r evd(切込み) −2m
m T(切削時間)−2Qmin O破損率 被削材 : SCM435 溝人材 工 具 :上Iこ同じ 切削条件: V−80m/m1n f =0.172〜0.20mm1 r evd=2r
nm ■−3m1n f=0.172 0.20mm/revで各々3回繰返
し、破損回数および破損 までの時間により破損率をめた。
0 wear-resistant work material: SCM435 (I (s30) tool:
FNIIR-44A, Tip 5NG432 (3) Grade 17'12A Cutting conditions: ■ (Cutting speed) -170m/m1nf (Feed) = 0.36mm/ r evd (Depth of cut) -2m
m T (cutting time) -2Qmin O breakage rate Work material: SCM435 Groove tool: Upper I Same cutting conditions: V-80m/m1n f =0.172~0.20mm1 r evd=2r
nm 1-3m1n f=0.172 Each test was repeated three times at 0.20 mm/rev, and the breakage rate was determined based on the number of breakages and the time until breakage.

この図かられかるように、超硬切削工具において切刃部
の面取りの角度、大きさを均一にコントロールすること
は安定した性能を得る上で非常に重要なことである。
As can be seen from this figure, it is very important to uniformly control the angle and size of the chamfer of the cutting edge of a carbide cutting tool in order to obtain stable performance.

ところが、ドリルの場合、スローアウエイチツ(4) プなどと1章って切刃形状の複雑さから砥石による研削
は不可能に近く、このため、超硬ドリルのチャンファ付
けは、ダイヤモンド砥粒を付着させたハントラッパーを
使用し、手作業で行っているのが実情であり、その結果
、チャンファの角度、大きさ1こ誤差(バラツキ)が生
じ、ドリル性能が不安定になっている。
However, in the case of drills, it is almost impossible to grind them with a grindstone due to the complexity of the cutting edge shape, such as the throw away thickness (4). The reality is that this is done manually using the attached hunt wrapper, and as a result, there is a 1-degree error (variation) in the angle and size of the chamfer, making the drilling performance unstable.

また、第3図に示す如き平担なチャンファを付したもの
は、すくい面及び逃げ面との交差部に鋭利なエッヂが残
るのでドリル寿命の低下1こつながる切刃のチッピング
が生じている。
Further, in the case of a drill with a flat chamfer as shown in FIG. 3, a sharp edge remains at the intersection of the rake face and the flank face, resulting in chipping of the cutting edge, which reduces the life of the drill.

一方、すくい面1と逃げ面2をアール曲面でつないだも
のは、チッピングは減るが切刃の被削材に対する喰い付
き性に優れない。
On the other hand, when the rake face 1 and the flank face 2 are connected by a curved radius surface, chipping is reduced, but the cutting edge is not excellent in biting into the work material.

(ハ)間順点を解決するための手段 本発明は、か\る間順点を解決した超硬ドリルとその刃
先強化法を提供するもので、第1の目的とするドリルは
、切刃部に付すチャンファのすくい面側における設置中
を逃げ面側のそれよりも大きくし、ざらに、このチャン
ファをすくい面と逃げ面に対しそれぞれ微小の丸味をも
って連続させ。
(c) Means for solving the problem of cutting edge The present invention provides a carbide drill that solves the problem of cutting edge and a method for strengthening its cutting edge. The length of the chamfer attached to the rake face side is made larger than that on the flank face side, and the chamfer is roughly continuous with each of the rake face and flank face with a slight roundness.

かつその全体を凸方向の彎曲面としたところに特徴を有
する。
The feature is that the entire surface is curved in a convex direction.

第5図乃至第7図にそのチャンファを代表的な超硬ドリ
ルに付した実施例を示す。図に示すよう1こ、超硬ドリ
ル10の外観形状は従来のドリルと殆んど変わらない。
5 to 7 show examples in which the chamfer is attached to a typical carbide drill. As shown in the figure, the external shape of the carbide drill 10 is almost the same as that of a conventional drill.

また、鋭角エッヂの除去のためにすくい面11と逃げ面
12の斜交部Iこ付されたチャンファ13の顛斜角も第
3図に示したθの値にはゾ近い角度である。即ち、チャ
ンファ13のすくい面側における設置中3を逃げ面側の
設置中すよりも大きくして刃先の角度が極端に鈍くなる
ことを避け、切れ味の低下を抑えている。但し、チャン
ファ13は従来の形状と異なり、全体1こ緩やかな凸円
弧面をなし、かつその両側部は更1こ小さな丸味をもっ
てすくい面11と逃げ面12につながっている。
Further, the bevel angle of the chamfer 13, which has an oblique intersection I between the rake face 11 and the flank face 12, is also close to the value of θ shown in FIG. 3 in order to remove an acute edge. In other words, the setting height 3 on the rake face side of the chamfer 13 is made larger than the setting height 3 on the flank face side to prevent the angle of the cutting edge from becoming extremely blunt, thereby suppressing a decrease in sharpness. However, unlike the conventional shape, the chamfer 13 has a slightly convex arcuate surface as a whole, and both sides thereof are connected to the rake face 11 and the flank face 12 with an even smaller roundness.

なお、ドリルの前切刃部に設けるチャンファは、その大
きさを切刃の位置に合わせてコントロールするのが望ま
しい。例えばドリル特有の間噸である中心切刃部の溶着
欠損、及び外周切刃部の摩耗は、チャンファの大きさを
回転中心側で大きく、外周に向かうに従って暫次小さく
すること昏こよって大巾に減少させることができる。こ
のチャンファの大きさ等の調整は後述する本発明の方法
によって容易かつ正確昏こ行える。
Note that it is desirable that the size of the chamfer provided at the front cutting edge of the drill be controlled in accordance with the position of the cutting edge. For example, to prevent welding defects on the center cutting edge and wear on the outer cutting edge, which are common problems of drills, it is necessary to increase the size of the chamfer near the center of rotation and gradually reduce it toward the outer periphery. can be reduced to The size of the chamfer can be easily and accurately adjusted by the method of the present invention, which will be described later.

以下iこ、上述のチャンファを付した本発明のドリルと
従来ドリルの切削性能1こ関する比較試験の結果を挙げ
る。
Below, we will list the results of a comparative test regarding the cutting performance of the drill of the present invention with the chamfer described above and the conventional drill.

試験に用いたドリルは、第8図のA(従来ドリル)、B
(本発明ドリル)で共に10vrm径である。
The drills used in the test are A (conventional drill) and B in Figure 8.
(drill of the present invention) and both have a diameter of 10vrm.

また、両者ともシンニング処理1こよりチゼル刃14の
11を極く小さくし、かつ、前切刃15を端面視におい
て同じ方向をこ彎曲させた。Aドリル1こは第3図の、
一方Bド′リル1こは第7図の刃先処理が施されている
。その処理部の諸寸法等は下表1の通りである。
Further, in both cases, the diameter 11 of the chisel blade 14 was made extremely small compared to the thinning process 1, and the front cutting blade 15 was curved in the same direction when viewed from the end. A drill 1 is shown in Figure 3.
On the other hand, one B drill has the cutting edge treated as shown in FIG. The various dimensions of the processing section are shown in Table 1 below.

表 1 この2種のドリルを各4本用意し、被削材550C(H
B250)にエマルジョンタイプの水溶性切削油を使っ
て穴加工を行った。そのときの切削トルり及びスラスト
力の測定結果は表2の通りで両者に大差はなかった。
Table 1 Four of these two types of drills were prepared, and the work material was 550C (H
B250) was drilled using an emulsion type water-soluble cutting oil. The measurement results of cutting torque and thrust force at that time are shown in Table 2, and there was no significant difference between the two.

表 2 また、切削条件V=50m/m i n、 f =0.
3rnm/ revで深さ30mmの穴を800穴あけ
たところ第8図1こ示すように、Aドリルには4本とも
図1こ示すように切刃部1こ微小なチッピングCが認め
られたがBドリルには何ら異常が見られなかった。これ
は、Aドリルの場合、チャンファと逃げ面及びすくい面
の交差部が鋭利であるのに対し、Bドリルは当該部1こ
鋭利さが無くかつ切刃部の厚みが多少なりともAドリル
よりも厚くなっていること1こよる結果と考えてよい。
Table 2 Also, cutting conditions V=50m/min, f=0.
When 800 holes with a depth of 30 mm were drilled at 3 nm/rev, as shown in Figure 8, all four A drills had minute chipping C on the cutting edge, as shown in Figure 1. No abnormalities were found in Drill B. This is because, in the case of the A drill, the intersection of the chamfer, flank face, and rake face is sharp, whereas the B drill has no sharpness in this area and the thickness of the cutting edge is somewhat thicker than that of the A drill. This can be thought of as a result of the fact that it is also thicker.

次1こ、同じドリルで更に試験を重ねたところ第9図1
こ示す結果を得た。即ち、Aドリルは1200穴に達す
る前に4本のサンプルのうち3本が切損し寿命に至った
が、Bドリルはいずれも1200穴加工後も継続使用が
可能であった。これは、微小チッピング及びa、b寸法
のバラツキの有無による結果と考えられる。
Next, after further tests using the same drill, Figure 9 1
We obtained the following results. That is, three of the four samples of the A drill were broken and reached the end of their service life before reaching 1,200 holes, but all of the B drills could be used continuously even after drilling 1,200 holes. This is considered to be the result of minute chipping and the presence or absence of variations in dimensions a and b.

次に、本発明の第2の目的である方法は、ブラシ又は弾
力性のあるパフ砥石に高硬度砥粒を付着。
Next, in the method which is the second object of the present invention, high hardness abrasive grains are attached to a brush or an elastic puff abrasive stone.

含浸、もしくは含有させ、これをドリル切刃に押し当て
、研削面を定められた方向に移動させること1こより上
述した形状のチャンファを付すところ1こ特徴をもつ。
One feature is that a chamfer having the above-mentioned shape is formed by impregnating or containing the material, pressing it against a drill cutting edge, and moving the grinding surface in a predetermined direction.

この方法の一例を示すのが第10図及び第11図である
。図の符号20は材料瞥こ好ましくは耐摩耗性のよい金
属やナイロン等の化合物質を使用した回転ブラシで、こ
のブラシにはダイヤモンドやシリコンカーバイドの如き
硬質砥粒21を付着させである。このブラシを図のよう
にチャック30等で保持したドリル10の切刃部1こ押
し付け、研削部即ちブラシの毛先部がすくい面11から
逃は面12側1こ又はその反対方向1こ移動するようブ
ラシを回転させると、毛先部の撓み1こより第7図に示
した形のチャンファが形成される。
An example of this method is shown in FIGS. 10 and 11. Reference numeral 20 in the figure is a rotating brush made of material, preferably a compound material such as a metal or nylon having good wear resistance, and hard abrasive grains 21 such as diamond or silicon carbide are attached to this brush. This brush is pressed against the cutting edge part of the drill 10 held by a chuck 30 or the like as shown in the figure, and the grinding part, that is, the tip of the brush moves from the rake surface 11 to the relief surface 12 side or once in the opposite direction. When the brush is rotated to do so, a chamfer in the shape shown in FIG. 7 is formed due to the bending of the tip of the bristles.

なお、ブラシの材質及び硬質砥粒の種類は、研削時間と
研削量を考慮して適宜選択すればよい。
Note that the material of the brush and the type of hard abrasive grains may be appropriately selected in consideration of the grinding time and amount of grinding.

また、ブラシは直線約1こ反復運動させるものを使用し
てよく硬質砥粒もブラシ1こ含有又は含浸させてよい。
Further, the brush may be one that can be repeatedly moved about once in a straight line, and one brush may also contain or be impregnated with hard abrasive grains.

さらに、ブラシに代え、弾力性のあるパフ砥石に硬質砥
粒を付着、又は含有させた研削具を使用した場合にも同
じ形状のチャンファを形成できる。
Furthermore, a chamfer having the same shape can be formed by using a grinding tool in which hard abrasive grains are attached to or contained in an elastic puff grindstone instead of a brush.

この方法によれば、複雑な形状の切刃に対してもブラシ
等を押し当てることができるのでブラシ等の研削具とド
リルを機成曲に保持して双方の位置や制度を制御しなが
ら研削を行うことにより、精度のよいチャンファを能率
良く付すことができる。また、切刃の研削具昏こ対する
突込み角度や突込み量を変えることによって、切刃中心
部と切刃外周部1こおけるチャンファの大きさや基準線
に対する基本的用度等を変えることも可能である。
According to this method, the brush etc. can be pressed against the cutting edge of a complex shape, so the grinding tool such as the brush and the drill are held in a mechanized bend and the position and precision of both are controlled while grinding. By doing this, it is possible to efficiently apply a chamfer with high precision. In addition, by changing the plunge angle and plunge amount of the cutting blade against the grinding tool, it is also possible to change the size of the chamfer at the center of the cutting blade and the outer circumference of the cutting blade, and the basic usage with respect to the reference line. be.

←) 効 果 り、上説明したように、本発明は、チャンファ形状の工
夫によって切れ味を低下させることなく切刃のチッピン
グを減少させたので、寿命の長い高性能の超硬ドリルを
提供できる。
←) Effects As explained above, the present invention reduces chipping of the cutting edge without reducing sharpness by devising the chamfer shape, so it is possible to provide a high-performance carbide drill with a long life.

また、本発明の方法は、従来手作業に頼らざるを得なか
ったチャンファ加工の機成化を可能にし、従ってドリル
のコスト引下げに大きく寄与し、また、機成化によりチ
ャンファの大きさ等のバラツキを防+hできるため、ド
リル性能をより一層高めると云う効果を有する。
In addition, the method of the present invention makes it possible to mechanize chamfer machining, which conventionally had to be done by hand, and thus greatly contributes to reducing the cost of drills. Since variations can be prevented, drill performance can be further improved.

なお、云う迄もなく、本発明の適用範囲には、切刃の一
部又は全体が超硬合金から成るドリルの全てが含まれる
Needless to say, the scope of the present invention includes all drills whose cutting blades are partially or entirely made of cemented carbide.

【図面の簡単な説明】[Brief explanation of drawings]

第1図は、従来の超硬ドリルの一例を示す側面図、第2
図はその正面図、第3図は第2図のX−X線1こ沿った
拡大断面図、第4図のfa) (1))は、旋削工具1
こおける面取りの大きさと角度を変えて靭性及び耐摩耗
性の変化状況を示すグラフ、第5図は本発明の超硬ドリ
ルの一例を示す側面図、第6図はその正面図、第7図は
第6図のY−Y線1こ沿った拡大断面図、第8図は試験
に用いた従来ドリルAと本発明ドリルBの前切刃部の性
状を示す斜視図、第9図は同上のドリルの耐久性を示す
グラフ、第10図は本発明の方法の一例を示す平面図、
第11図はその正面図である。 10・・・超硬ドリル、11・・・すくい面、12・・
・逃げ面、13・・・チャンファ、14・・・チゼル刃
、15・・・前切刃、20・・・回転ブラシ、21・・
・高質砥粒。 30・・・チャック 同 代理人 鎌 1) 文 ニ *仔f¥− 区 卦 幕(=) f 特開昭GO−221208(5) 嵌 に 帽) 丘 U ÷ 弓H(ぐ姪
Figure 1 is a side view showing an example of a conventional carbide drill; Figure 2 is a side view showing an example of a conventional carbide drill;
The figure is a front view, FIG. 3 is an enlarged cross-sectional view taken along the line X-X in FIG. 2, and fa) (1)) in FIG.
Graph showing changes in toughness and wear resistance by changing the size and angle of the chamfer in the groove, FIG. 5 is a side view showing an example of the carbide drill of the present invention, FIG. 6 is a front view thereof, and FIG. 7 is an enlarged sectional view taken along the Y-Y line 1 in Fig. 6, Fig. 8 is a perspective view showing the properties of the front cutting edge of the conventional drill A and the drill B of the present invention used in the test, and Fig. 9 is the same as above. A graph showing the durability of the drill, FIG. 10 is a plan view showing an example of the method of the present invention,
FIG. 11 is a front view thereof. 10... Carbide drill, 11... Rake face, 12...
- Flank surface, 13... Chamfer, 14... Chisel blade, 15... Front cutting blade, 20... Rotating brush, 21...
・High quality abrasive grains. 30...Chuck same agent sickle 1) sentence ni*zif ¥- ku hexa curtain (=) f JP-A-Sho GO-221208 (5) fit in hat) hill U ÷ bow H (gu niece

Claims (4)

【特許請求の範囲】[Claims] (1) すくい面と逃げ面の斜交したエッヂを、双方の
面1こ交わる微小中のチャンファの付設によって除去し
刃先を強化した超硬ドリルにおいて、上記チャンファの
すくい面側1こおける設置l]を逃げ面側のそれよりも
大きくし、さらにこのチャンファをすくい面と逃げ面昏
こ対しそれぞれ微小の丸味をもって連続させ、かつその
全体を凸方向の彎曲面としたことを特徴とする超硬ドリ
ル。
(1) In a carbide drill in which the cutting edge is strengthened by removing the oblique edges of the rake face and flank by attaching a small to medium-sized chamfer that intersects one point on both sides, the chamfer is installed at one point on the rake face side. ) is larger than that on the flank side, and the chamfer is continuous with a slight roundness on the rake face and the flank face, respectively, and the entire chamfer is a curved surface in a convex direction. Drill.
(2) 上記チャンファを回転中心側で大きく、外周1
こ向かう1こ従って暫次小さくしたことを特徴とする特
許請求の範囲第(1)項記載の超硬ドリル。
(2) The chamfer is larger on the rotation center side, and the outer circumference is 1
The cemented carbide drill according to claim 1, characterized in that the diameter of the cemented carbide drill is reduced accordingly.
(3) 回転ブラシ、直線的1こ反復運動させるブラシ
又は弾力性のあるパフ砥石に高硬度砥粒を付着含浸もし
くは含有させ、これをドリル切刃に押し当て、ブラシ又
はパフ砥石の研削面を切刃のすくい面側から逃げ面側1
こ又はその反対方向に移動させること1こよりすくい面
と逃げ面の斜交するエッヂ部に、すくい面側の設置中が
逃げ面側のそれよりも大きく、かつ微小の丸味をもって
すくい面と逃げ面に連なる凸方向に彎曲したチャンファ
を付すことを特徴とする超硬ドリルの刃先強化法。
(3) High-hardness abrasive particles are adhered to or impregnated into a rotating brush, a brush that is repeatedly moved in a straight line, or an elastic puff whetstone, and this is pressed against a drill cutting edge, so that the grinding surface of the brush or puff whetstone is From the rake face side of the cutting blade to the flank side 1
To move in this direction or in the opposite direction: 1) At the edges where the rake face and flank intersect, the rake face and flank face are placed so that the rake face side is larger than the flank face side and has a slight roundness. A method for strengthening the cutting edge of a carbide drill, which is characterized by adding a chamfer that is curved in a convex direction.
(4) 上記高硬度砥粒としてダイヤモンド又はシリコ
ンカーバイトの砥粒を使用することを特徴とする特許請
求の範囲第(3)項に記載の超硬ドリルの刃先強化法。
(4) The method for strengthening the cutting edge of a carbide drill according to claim (3), characterized in that diamond or silicon carbide abrasive grains are used as the high-hardness abrasive grains.
JP7688884A 1984-04-13 1984-04-13 Very hard drill and method of strengthening cutting edge thereof Granted JPS60221208A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP7688884A JPS60221208A (en) 1984-04-13 1984-04-13 Very hard drill and method of strengthening cutting edge thereof

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP7688884A JPS60221208A (en) 1984-04-13 1984-04-13 Very hard drill and method of strengthening cutting edge thereof

Publications (2)

Publication Number Publication Date
JPS60221208A true JPS60221208A (en) 1985-11-05
JPH0134727B2 JPH0134727B2 (en) 1989-07-20

Family

ID=13618174

Family Applications (1)

Application Number Title Priority Date Filing Date
JP7688884A Granted JPS60221208A (en) 1984-04-13 1984-04-13 Very hard drill and method of strengthening cutting edge thereof

Country Status (1)

Country Link
JP (1) JPS60221208A (en)

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH0379211U (en) * 1989-12-05 1991-08-13
JP3030741U (en) * 1995-12-30 1996-11-05 日本セラテック株式会社 Drill blade
WO2010128085A1 (en) * 2009-05-06 2010-11-11 Element Six Limited Superhard insert
WO2014034495A1 (en) * 2012-08-30 2014-03-06 アイシン精機株式会社 Grinding method for skiving cutter and grinding device for skiving cutter
US20170028481A1 (en) * 2013-12-26 2017-02-02 Mitsubishi Materials Corporation Drill insert and indexable drill
US20170274460A1 (en) * 2014-09-19 2017-09-28 Sumitomo Electric Hardmetal Corp. Drill
US20200238469A1 (en) * 2019-01-30 2020-07-30 Kennametal Inc. Method for producing a cutting tool and cutting tool

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH0379211U (en) * 1989-12-05 1991-08-13
JP3030741U (en) * 1995-12-30 1996-11-05 日本セラテック株式会社 Drill blade
WO2010128085A1 (en) * 2009-05-06 2010-11-11 Element Six Limited Superhard insert
CN102458730A (en) * 2009-05-06 2012-05-16 六号元素有限公司 Superhard insert
WO2014034495A1 (en) * 2012-08-30 2014-03-06 アイシン精機株式会社 Grinding method for skiving cutter and grinding device for skiving cutter
JP2014046391A (en) * 2012-08-30 2014-03-17 Aisin Seiki Co Ltd Grinding method of cutter for skiving work and grinding device of the cutter for skiving work
US20170028481A1 (en) * 2013-12-26 2017-02-02 Mitsubishi Materials Corporation Drill insert and indexable drill
US20170274460A1 (en) * 2014-09-19 2017-09-28 Sumitomo Electric Hardmetal Corp. Drill
US10155269B2 (en) * 2014-09-19 2018-12-18 Sumitomo Electric Hardmetal Corp. Drill
US20200238469A1 (en) * 2019-01-30 2020-07-30 Kennametal Inc. Method for producing a cutting tool and cutting tool

Also Published As

Publication number Publication date
JPH0134727B2 (en) 1989-07-20

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