JPH06312376A - Ultra-abrasive wheel embedded therein with striplike chips, for precise cutting - Google Patents

Ultra-abrasive wheel embedded therein with striplike chips, for precise cutting

Info

Publication number
JPH06312376A
JPH06312376A JP9980493A JP9980493A JPH06312376A JP H06312376 A JPH06312376 A JP H06312376A JP 9980493 A JP9980493 A JP 9980493A JP 9980493 A JP9980493 A JP 9980493A JP H06312376 A JPH06312376 A JP H06312376A
Authority
JP
Japan
Prior art keywords
chips
abrasive
abrasive grain
grain layer
wheel
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
JP9980493A
Other languages
Japanese (ja)
Other versions
JP2972049B2 (en
Inventor
Kenichiro Kumamoto
健一郎 熊本
Keizo Takeuchi
恵三 竹内
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.)
Noritake Diamond Industries Co Ltd
Original Assignee
Noritake Diamond Industries Co 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 Noritake Diamond Industries Co Ltd filed Critical Noritake Diamond Industries Co Ltd
Priority to JP9980493A priority Critical patent/JP2972049B2/en
Publication of JPH06312376A publication Critical patent/JPH06312376A/en
Application granted granted Critical
Publication of JP2972049B2 publication Critical patent/JP2972049B2/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

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Abstract

PURPOSE:To enhance the efficiency of discharge of chips while maintaining a low chipping value by embedding strip-like chips having a wearing speed which is different from that of an abrasive layer continuously formed over the outer periphery of an ultra-abrasive wheel, in the outer surface of the abrasive layer in a staggering pattern. CONSTITUTION:An precisely cutting ultra-abrasive wheel comprises a ring-like mother abrasive layer composed of #600 diamond abrasive having a degree of concentration of 100 (25vol.%) and binder of CU80-Sn20(wt.%), and formed over the outer periphery of a disc-like substrate 1. Further, strip-like chips 3 are embedded in the front and rear surfaces of the mother abrasive layer 2. Further, the working hardness of the chips 3 is in a range of 50 to 90, or 110 to 150 with respect to the working hardness of the abrasive layer 2 which is set to 100. Accordingly, the abrasion progressing speed during use is retarded. Further, the chips 3, is formed of the same abrasive as that of the abrasive layer 3 with the use of Cu72-Cn18-Fe10 as a binder, are arranged at pitches of, for example, 150mm.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】本発明は、セラミックス、フェラ
イト、水晶、超硬合金、焼入鋼などの切断に用いる精密
切断用超砥粒ホイールに関する。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a superabrasive wheel for precision cutting, which is used for cutting ceramics, ferrite, quartz, cemented carbide, hardened steel and the like.

【0002】[0002]

【従来の技術】従来よりセラミックス、フェライト、水
晶、超硬合金、焼入鋼などの切断用として、金属製台金
の外周にダイヤモンドや立方晶窒化ほう素などの超硬質
砥粒層を備えたものが使用されている。
2. Description of the Related Art Conventionally, for cutting ceramics, ferrite, quartz, cemented carbide, hardened steel, etc., a metal base metal has been provided with an ultra-hard abrasive grain layer such as diamond or cubic boron nitride. Things are being used.

【0003】特に脆性材料や難削材料の精密切断用超砥
粒ホイールとしては、加工面端部のチッピングが少なく
良好な加工面を得やすいように、基板外周縁に連続した
砥粒層を有するホイールが使用されている。ところがこ
のようなホイールは、砥粒層がリング状に連続したもの
であるために、研削液の供給が不足し、加工によって発
生する切粉の排出が充分にできず目づまり現象を起こし
易い。
Particularly, as a superabrasive grain wheel for precision cutting of brittle materials and difficult-to-cut materials, it has a continuous abrasive grain layer on the outer peripheral edge of the substrate so that a good machined surface can be easily obtained with less chipping at the end of the machined surface. Wheels are used. However, in such a wheel, since the abrasive grain layer is continuous in a ring shape, the supply of the grinding fluid is insufficient, and the chips generated by the processing cannot be sufficiently discharged, which easily causes the clogging phenomenon.

【0004】一方切粉の排出を良くして加工能率を向上
させたものとして、砥粒層にスリットをいれたもの、
砥粒層をセグメントタイプとしたもの、砥粒層側面
に波形形状を付与したものなどが実用されている。しか
しながらこのような構造は、基本的に砥粒層が被削材へ
断続的に衝突するため、チッピングが大きくなり、特に
精密加工用としては用いることが出来ない。
On the other hand, as one that improves the machining efficiency by improving the discharge of chips, one that has slits in the abrasive grain layer,
A segment type abrasive grain layer, a corrugated side surface of the abrasive grain layer, and the like are in practical use. However, such a structure basically causes the abrasive grain layer to intermittently collide with the work material, resulting in large chipping, and cannot be used particularly for precision machining.

【0005】また、特公昭61−5854号公報には、
メタルボンドホイールの側面にレジンボンドよりなる第
2の砥粒層を設け、粗切断後仕上加工も同時に行なうよ
うにした2層構造のホイールが提案されている。しかし
ながらこのホイールは、レジンボンド砥粒層の摩耗が早
いため加工精度が狂いやすく、また2層式であるために
ホイールが厚くなり被削加工代が大きくなるという問題
がある。
Further, Japanese Patent Publication No. 61-5854 discloses that
A wheel having a two-layer structure has been proposed in which a second abrasive grain layer made of a resin bond is provided on a side surface of a metal bond wheel, and finishing processing is also performed after rough cutting at the same time. However, in this wheel, there is a problem in that the resin bond abrasive grain layer wears quickly, and thus the processing accuracy is likely to vary, and because the wheel is a two-layer type, the wheel becomes thick and the machining cost increases.

【0006】[0006]

【発明が解決しようとする課題】本発明は精密切断用超
砥粒ホイールにおける上記問題点を解消するもので、チ
ッピング量を低めに維持しつつ、かつ研削液の供給、切
断によって生じる切粉の排出効果に優れた精密切断用超
砥粒ホイールを得ることを目的とする。
DISCLOSURE OF THE INVENTION The present invention solves the above problems in a superabrasive grain wheel for precision cutting, and maintains the chipping amount at a low level and removes the chips generated by the supply and cutting of the grinding fluid. The purpose of the present invention is to obtain a superabrasive wheel for precision cutting, which has an excellent discharging effect.

【0007】[0007]

【課題を解決するための手段】本発明は上記目的を達成
するために、基板外周縁に連続した砥粒層を有するホイ
ールや基板全体が砥粒層で形成されたホイール等、少な
くとも外周部に連続した砥粒層を有する精密切断用超砥
粒ホイールにおいて、前記砥粒層の表裏面に同砥粒層の
摩耗速度と異なる摩耗速度のたんざく状砥粒層チップ
(以下たんざく状チップという。)を千鳥状に埋没配置
したことを特徴とする。
In order to achieve the above object, the present invention has at least an outer peripheral portion such as a wheel having a continuous abrasive grain layer on the outer peripheral edge of a substrate or a wheel in which the entire substrate is formed of an abrasive grain layer. In a superabrasive grain wheel for precision cutting having a continuous abrasive grain layer, a grain-shaped abrasive grain layer chip (hereinafter referred to as a grain-shaped chip) having a wear rate different from that of the abrasive grain layer on the front and back surfaces of the abrasive grain layer. .) Are buried in a zigzag pattern.

【0008】ここで、たんざく状チップの厚みを、砥粒
層の厚みの1/3〜2/3の範囲とすることによって、
砥粒層の強度を損なうことなく埋設配置することが可能
となる。
[0008] Here, by setting the thickness of the tumble-shaped chip in the range of 1/3 to 2/3 of the thickness of the abrasive grain layer,
It is possible to embed the abrasive grain layer without impairing its strength.

【0009】また、摩耗速度の差は、ボンド結合度、砥
粒集中度または砥粒粒度の少なくとも1つを異ならせる
ことによって所定のものを得ることができるが、特に、
中央の母砥粒層の作用硬さを100とした場合、たんざ
く状チップの作用硬さを50〜90、又は110〜15
0の範囲とすれば、母砥粒層とたんざく状チップとの摩
耗差によって、切粉の排出効果に優れかつチッピングの
発生が少ない適度な段差を形成することができる。
The difference in the wear rate can be obtained by varying at least one of the bond bond degree, the abrasive grain concentration degree, and the abrasive grain size.
When the working hardness of the central mother abrasive grain layer is set to 100, the working hardness of the tuna chips is 50 to 90, or 110 to 15
Within the range of 0, due to the difference in wear between the mother abrasive grain layer and the chip-shaped chips, it is possible to form an appropriate step having an excellent chip discharging effect and less chipping.

【0010】たんざく状チップは、メタルボンド組成に
おいては、金属粉末及び砥粒、また必要に応じてフィラ
ーを添加し、湿式または乾式で混合攪拌後、金型に薄く
伸ばし、熱と圧力を加え、これを焼成して製造する。そ
の際、後に母砥粒層と共に本焼成を加えるので、充分な
緻密度を得る必要はなく、90〜95%程度の緻密度で
よい。
In the metal bond composition of the tuna-shaped chip, metal powder and abrasive grains, and if necessary, a filler are added, and the mixture is mixed and stirred by a wet or dry system, and then thinly spread on a mold, and heat and pressure are applied. , This is baked to be manufactured. At this time, since the main calcination is added later together with the mother abrasive grain layer, it is not necessary to obtain a sufficient density, and a density of about 90 to 95% is sufficient.

【0011】また、レジンボンド組成においては、レジ
ンボンド粉末および砥粒、また必要に応じてフィラーを
添加し、溶媒中で粘着剤を加えペースト状に混練後、シ
ート状に伸ばし、これを乾燥させて製造する。
In the resin bond composition, resin bond powder and abrasive grains and, if necessary, a filler are added, an adhesive is added in a solvent, and the mixture is kneaded into a paste, spread into a sheet, and dried. To manufacture.

【0012】このたんざく状チップを用い、以下の手法
で本発明の精密切断用超砥粒ホイールを製造する。
Using this tumble-shaped tip, the superabrasive grain wheel for precision cutting of the present invention is manufactured by the following method.

【0013】焼結に使用する金型は、第4図に示すよう
に、基板1を挟む中型5、外型4、砥粒層に圧力を加え
る上押型6,下押型7で構成される。この上下押型6,
7内面に、たんざく状チップ3を熱飛散性接着剤を用い
所望する間隔で千鳥状となるように接着する。次いで中
型5で基板を挟み、下押型7及び外型4を組み、中型5
と外型4との隙間(下押型7の上)へ母砥粒層のボンド
と超砥粒の混合粉を充填する。次いで上押型6のたんざ
くチップ3を張り付けた面を充填した混合粉側に向けて
伏せ密封する。このとき、下押し型側7と上押型6に接
着したくたんざくチップ3が所定の千鳥状となるよう
に、上下押し型6,7と外型4に位置合わせガイド8を
設ける。この状態で熱と圧力を加えて焼結を行なう。
As shown in FIG. 4, the die used for sintering is composed of a middle die 5 sandwiching the substrate 1, an outer die 4, an upper die 6 and a lower die 7 for applying pressure to the abrasive grain layer. This up and down die 6,
The chip-shaped chips 3 are adhered to the inner surface of the device 7 using a heat-dissipating adhesive in a zigzag pattern at desired intervals. Next, the substrate is sandwiched by the middle mold 5, the lower press mold 7 and the outer mold 4 are assembled, and the middle mold 5
A bond between the mother abrasive grain layer and the mixed powder of superabrasive grains is filled in a gap between the outer die 4 and the outer die 4 (on the lower die 7). Next, the surface of the upper die 6 to which the tuna chips 3 are attached is turned down and sealed toward the filled mixed powder side. At this time, the vertical guide dies 6, 7 and the outer die 4 are provided with alignment guides 8 so that the shavings chips 3 adhered to the lower press die side 7 and the upper push die 6 have a predetermined zigzag shape. In this state, heat and pressure are applied to sinter.

【0014】焼結温度は、メタルボンドの場合、Cuや
Snなどの金属粉末を焼結させるために、500℃以上
の高温で行い、レジンボンドの場合は、フェノール等の
樹脂をボンドとした場合、熱盤上で150〜200℃に
加熱して行なう。
In the case of metal bond, the sintering temperature is 500 ° C. or higher in order to sinter the metal powder such as Cu and Sn, and in the case of resin bond, the resin such as phenol is used as the bond. , Heating to 150 to 200 ° C. on a heating plate.

【0015】さらに、焼結された精密切断用超砥粒ホイ
ールの砥粒層表面を研磨することによって、母砥粒層と
たんざく状チップの何れかがより多く削り取られ、連続
した砥粒層の側面部に微小かつなだらかな段差を形成し
た製品が完成する。
Furthermore, by polishing the surface of the abrasive grain layer of the sintered precision cutting superabrasive grain wheel, either the mother abrasive grain layer or the tumble-shaped chip is scraped off more, and the continuous abrasive grain layer is removed. A product with a minute and gentle step formed on the side surface of is completed.

【0016】[0016]

【作用】本発明の精密切断用超砥粒ホイールにおいて
は、使用に伴って母砥粒層及びたんざく状チップが局部
摩耗し、母砥粒層とたんざく状チップの境界部に微小な
段差が形成される。この微小な段差によって切断加工の
際生じる切粉が、外部に効率良く排出されるようにな
る。また、研削液は基板側面からも段差を通って研削点
へ容易に供給されるようになり、研削焼けの発生も減少
する。
In the superabrasive grain wheel for precision cutting of the present invention, the mother abrasive grain layer and the chip-shaped chips are locally worn with use, and a minute step is formed at the boundary between the mother abrasive grain layer and the chip-shaped chips. Is formed. The chips generated during the cutting process due to the minute steps can be efficiently discharged to the outside. Further, the grinding liquid can be easily supplied from the side surface of the substrate to the grinding point through the step, and the occurrence of grinding burn is reduced.

【0017】[0017]

【実施例】図1は本発明の一実施例である精密切断用超
砥粒ホイールの部分平面図、図2は図1に示す精密切断
用超砥粒ホイールの底面図、図3は使用後における精密
切断用超砥粒ホイールの底面図で、150D ×1T ×3
X の円板状基板1外周縁に、集中度100(25体積
%)の♯600の合成ダイヤモンド砥粒と、Cu80−
Sn20(重量%)の結合材を用いた連続したリング状
の母砥粒層2が形成され、この母砥粒層2の表裏面にた
んざく状チップ3が埋設配置されている。
FIG. 1 is a partial plan view of a superabrasive grain wheel for precision cutting according to an embodiment of the present invention, FIG. 2 is a bottom view of the superabrasive grain wheel for precision cutting shown in FIG. 1, and FIG. Is a bottom view of a superabrasive wheel for precision cutting at 150 D × 1 T × 3
On the outer peripheral edge of the disk-shaped substrate 1 of X , a synthetic diamond abrasive grain of # 600 having a concentration of 100 (25% by volume) and Cu80-
A continuous ring-shaped mother abrasive grain layer 2 is formed using a binder of Sn20 (wt%), and the tumble-shaped chips 3 are embedded in the front and back surfaces of this mother abrasive grain layer 2.

【0018】たんざく状チップ3は、寸法が5L ×3W
×0.3T で、15mmピッチで設けられており、母砥
粒層2と同じ砥粒を用い、結合剤として、Cu72−S
n18−Fe10を用いた。これによって、図3に示す
ように、母砥粒層2よりも硬質(砥粒層の作用硬さを1
00とした場合130)で使用時の摩耗進行速度が遅い
ものとなった。
The chip-shaped chip 3 has dimensions of 5 L x 3 W.
× 0.3 T , provided at a pitch of 15 mm, using the same abrasive grains as the mother abrasive grain layer 2 and using Cu72-S as a binder.
n18-Fe10 was used. As a result, as shown in FIG. 3, it is harder than the mother abrasive grain layer 2 (the working hardness of the abrasive grain layer is 1
In the case of 00, 130), the rate of progress of wear during use was slow.

【0019】この実施例品を用いて、実際に加工試験を
行なった。
A working test was actually carried out using this example product.

【0020】比較例としてたんざく状チップを持たない
従来の精密切断用超砥粒ホイールを用いた。比較例1
は、結合剤として実施例1の母砥粒層と同じ配合のもの
を、また比較例2として、実施例1のたんざく状チップ
と同一組成のものを使用した。なお他の条件は実施例と
同一である。
As a comparative example, a conventional superabrasive grain wheel for precision cutting, which does not have a scrap-shaped chip, was used. Comparative Example 1
As the binder, the same composition as the mother abrasive grain layer of Example 1 was used, and as the comparative example 2, the same composition as the pomegranate-shaped chip of Example 1 was used. The other conditions are the same as those in the example.

【0021】加工条件は次の通りである。The processing conditions are as follows.

【0022】被削材:フェライト ホイール周速度:1600m/min 切込み:5mm 送り速度:0.6m/ min 切断長さ:50mm×200カット 合計10m 研削液: 水溶液 結果を表1に示す。Work Material: Ferrite Wheel peripheral speed: 1600 m / min Depth of cut: 5 mm Feed rate: 0.6 m / min Cutting length: 50 mm x 200 cuts Total 10 m Grinding liquid: aqueous solution The results are shown in Table 1.

【0023】[0023]

【表1】 このように、作用硬さが母砥粒層よりも硬いたんざく状
チップを配置した実施例品1は、母砥粒層部分の摩耗量
がたんざく状チップよりも大きく境界部に4〜6μmの
微小段差が生じた。これによって、ホイール側面の被削
材への接触抵抗が軽減され電力値が低く切れ味良好とな
り、またチッピングも少なかった。
[Table 1] In this way, in Example product 1 in which the working chips having the working hardness harder than the mother abrasive grain layer were arranged, the wear amount of the mother abrasive grain layer portion was larger than that of the mother chips and the boundary portion was 4 to 6 μm. There was a small step. As a result, the contact resistance to the work material on the side surface of the wheel was reduced, the power value was low, the sharpness was good, and the chipping was small.

【0024】試験例2として、砥粒集中度を変化させた
母砥粒層とたんざく状チップを用い実施例2と、比較例
3とを用い加工試験を行なった。実施例2および比較例
3のホイール諸元を表2に示す。
As Test Example 2, a working test was carried out using Example 2 and Comparative Example 3 using a mother abrasive grain layer having a varying degree of concentration of abrasive grains and a tumble-shaped tip. Table 2 shows the wheel specifications of Example 2 and Comparative Example 3.

【0025】[0025]

【表2】 切断条件は次の通りである。[Table 2] The cutting conditions are as follows.

【0026】被削材:超硬合金 研削機械:横軸平面研削盤 ホイール周速度:1600m/min 切込み:2mm 送り速度:0.5 m/min 切断長さ:100mm× 100カット 合計 10
m 研削液:水溶液 結果を表3に示す。
Work Material: Cemented Carbide Grinding Machine: Horizontal Axis Surface Grinder Wheel peripheral speed: 1600 m / min Depth of cut: 2 mm Feed rate: 0.5 m / min Cutting length: 100 mm x 100 cuts Total 10
m Grinding liquid: aqueous solution The results are shown in Table 3.

【0027】[0027]

【表3】 たんざく状チップと母砥粒層の集中度を変えた実施例2
は、摩耗速度に差が生じ微小段差が発生した。比較例3
は砥粒層の目つぶれ及び切粉の目づまりにより次第に切
断負荷が高くなり、最終的に焼けが発生したが、本発明
ホイールは微小段差からの研削液の供給が良好で、目つ
ぶれ、目づまりを防止し、焼けは発生せず良好な切れ味
を持続した。
[Table 3] Example 2 in which the degree of concentration of the scrap chips and the mother abrasive grain layer was changed
Had a difference in wear rate, and a minute step was generated. Comparative Example 3
Although the cutting load gradually increased due to the crushing of the abrasive grain layer and the clogging of the cutting chips, and finally the burning occurred, the wheel of the present invention is well supplied with the grinding fluid from the minute step, and the crushing Prevents jams, no burning occurred, and good sharpness was maintained.

【0028】[0028]

【発明の効果】本発明によって以下の効果を奏すること
ができる。
According to the present invention, the following effects can be obtained.

【0029】(1)切粉の排出が良くなり目詰まり現象
を低減でき、高能率切断が可能となった。
(1) The discharge of chips is improved, the clogging phenomenon can be reduced, and highly efficient cutting is possible.

【0030】(2)砥粒層側面に生じる段差はなだらか
であるため、加工物の加工品位を損なうことはない。
(2) Since the step formed on the side surface of the abrasive grain layer is gentle, it does not impair the processing quality of the workpiece.

【0031】(3)側面への加工物への接触面積が減少
するため、切断抵抗が減少する。
(3) Since the contact area of the side surface with the workpiece is reduced, the cutting resistance is reduced.

【0032】(4)たんざくチップを耐摩耗性の高い組
成にすることによって、溝入れ加工に使用した場合溝底
部のコーナーだれの発生を防止できる。
(4) By using a composition having a high wear resistance for the Tanzaku chip, it is possible to prevent the occurrence of corner sag at the bottom of the groove when used for grooving.

【0033】(5)側面のクリアランスより研削液が研
削点まで供給されやすくなり焼け防止に有効である。
(5) Since the grinding liquid is more easily supplied to the grinding point than the clearance on the side surface, it is effective in preventing burning.

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

【図1】本発明の一実施例である精密切断用超砥粒ホイ
ールの部分平面図である。
FIG. 1 is a partial plan view of a superabrasive wheel for precision cutting which is an embodiment of the present invention.

【図2】図1に示す精密切断用超砥粒ホイールの底面図
である。
FIG. 2 is a bottom view of the superabrasive wheel for precision cutting shown in FIG.

【図3】図2に示す精密切断用超砥粒ホイールの使用後
の状況を示す底面図である。
FIG. 3 is a bottom view showing a situation after using the superabrasive wheel for precision cutting shown in FIG.

【図4】本発明の精密切断用超砥粒ホイールの製造方法
を示す断面図である。
FIG. 4 is a cross-sectional view showing a method of manufacturing a superabrasive wheel for precision cutting of the present invention.

【符号の説明】[Explanation of symbols]

1 基板 2 母砥粒層 3 たんざく状チップ 4 外型 5 中型 6 上型 7 下型 1 Substrate 2 Mother Abrasive Grain Layer 3 Tandem Chip 4 Outer Mold 5 Middle Mold 6 Upper Mold 7 Lower Mold

Claims (2)

【特許請求の範囲】[Claims] 【請求項1】 少なくとも外周部に連続した砥粒層を有
する精密切断用超砥粒ホイールにおいて、前記砥粒層の
表裏面に同砥粒層の摩耗速度と異なる摩耗速度のたんざ
く状チップを千鳥状に埋没配置したことを特徴とする精
密切断用超砥粒ホイール。
1. A superabrasive grain wheel for precision cutting having a continuous abrasive grain layer on at least an outer peripheral portion thereof, and a tumble-shaped chip having a wear rate different from that of the abrasive grain layer on the front and back surfaces of the abrasive grain layer. A superabrasive wheel for precision cutting characterized by being buried in a zigzag pattern.
【請求項2】 前記砥粒層の作用硬さを100とした場
合、前記たんざく状超砥粒層チップの作用硬さが50〜
90、又は110〜150であることを特徴とする請求
項1記載の精密切断用超砥粒ホイール。
2. When the working hardness of the abrasive grain layer is 100, the working hardness of the tumble-shaped superabrasive grain layer chip is 50 to 50.
90 or 110-150, The superabrasive grain wheel for precision cutting according to claim 1, characterized in that.
JP9980493A 1993-04-26 1993-04-26 Super-abrasive wheel for precision cutting with embedded tangled chips Expired - Fee Related JP2972049B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP9980493A JP2972049B2 (en) 1993-04-26 1993-04-26 Super-abrasive wheel for precision cutting with embedded tangled chips

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP9980493A JP2972049B2 (en) 1993-04-26 1993-04-26 Super-abrasive wheel for precision cutting with embedded tangled chips

Publications (2)

Publication Number Publication Date
JPH06312376A true JPH06312376A (en) 1994-11-08
JP2972049B2 JP2972049B2 (en) 1999-11-08

Family

ID=14257067

Family Applications (1)

Application Number Title Priority Date Filing Date
JP9980493A Expired - Fee Related JP2972049B2 (en) 1993-04-26 1993-04-26 Super-abrasive wheel for precision cutting with embedded tangled chips

Country Status (1)

Country Link
JP (1) JP2972049B2 (en)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH09314453A (en) * 1996-05-28 1997-12-09 Noritake Dia Kk Wire saw
WO1998058770A1 (en) * 1997-06-25 1998-12-30 Minnesota Mining And Manufacturing Company Superabrasive cutting surface
JPH11156724A (en) * 1997-11-28 1999-06-15 Kozo Ishizaki Preliminary molded material and girding wheel made of said preliminary molded material having controlled abrasive grain intervals
JP2000510773A (en) * 1996-11-21 2000-08-22 ノートン カンパニー Abrasive tool with split groove
JP2018001392A (en) * 2016-07-08 2018-01-11 スピードファム株式会社 Abradant

Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH09314453A (en) * 1996-05-28 1997-12-09 Noritake Dia Kk Wire saw
JP2000510773A (en) * 1996-11-21 2000-08-22 ノートン カンパニー Abrasive tool with split groove
WO1998058770A1 (en) * 1997-06-25 1998-12-30 Minnesota Mining And Manufacturing Company Superabrasive cutting surface
US6110031A (en) * 1997-06-25 2000-08-29 3M Innovative Properties Company Superabrasive cutting surface
EP1306166A1 (en) * 1997-06-25 2003-05-02 Minnesota Mining And Manufacturing Company Method for making a superabrasive cutting surface
JPH11156724A (en) * 1997-11-28 1999-06-15 Kozo Ishizaki Preliminary molded material and girding wheel made of said preliminary molded material having controlled abrasive grain intervals
JP2018001392A (en) * 2016-07-08 2018-01-11 スピードファム株式会社 Abradant
WO2018008551A1 (en) * 2016-07-08 2018-01-11 スピードファム株式会社 Abrasive material
CN109195749A (en) * 2016-07-08 2019-01-11 创技股份有限公司 Grind material

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