JPH04124297A - Production of electrodeposition tool - Google Patents

Production of electrodeposition tool

Info

Publication number
JPH04124297A
JPH04124297A JP2243303A JP24330390A JPH04124297A JP H04124297 A JPH04124297 A JP H04124297A JP 2243303 A JP2243303 A JP 2243303A JP 24330390 A JP24330390 A JP 24330390A JP H04124297 A JPH04124297 A JP H04124297A
Authority
JP
Japan
Prior art keywords
abrasive grains
film
frame
grains
metal
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.)
Pending
Application number
JP2243303A
Other languages
Japanese (ja)
Inventor
Tomita Suzuki
鈴木 富太
Yuichi Sumida
隅田 雄一
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.)
NSK Ltd
Original Assignee
NSK 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 NSK Ltd filed Critical NSK Ltd
Priority to JP2243303A priority Critical patent/JPH04124297A/en
Publication of JPH04124297A publication Critical patent/JPH04124297A/en
Pending legal-status Critical Current

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  • Electroplating Methods And Accessories (AREA)

Abstract

PURPOSE:To produce an electrodeposition tool without requiring the finishing of the grained surface by electrolysis while simply removing a frame mold and reusing it by forming a film of a low m.p. metal on the molding surface of the mold, melting the film by heating and arranging abrasive grains. CONSTITUTION:A film 3 of a low m.p. metal such as Pb or Sn is formed by plating on the molding surface 2 of a frame mold 1 and abrasive grains 4 of diamond, cubic BN, etc., are adhered to the surface 2. At this time, the film 3 is melted, the grains 4 are bitten in the molten film and this film is solidified by cooling to temporarily fix the grains 4. An Ni plating layer 5 is then formed on the grains 4 and the film 3 is allowed to flow out by heating to the m.p. to obtain an intermediate product with the grains 4 embedded in the outside of the thick Ni plating layer 5 by about 2/3 of the diameter. A core metal 6 is put in the product and a sintered alloy 7 having a relatively low m.p. is melted, poured and solidified by cooling to complete an electrodeposition tool 10.

Description

【発明の詳細な説明】 〔産業上の利用分野〕 本発明は、ダイヤモンドやCBN (立方晶窒化はう素
)を砥粒とした電着砥石及びロータリードレッサやイン
プリドレッサ等の電着工具の製造方法に関する。
[Detailed Description of the Invention] [Industrial Application Field] The present invention is directed to the production of electrodeposited tools such as electroplated grindstones and rotary dressers and implied dressers using diamond or CBN (cubic boron nitride) abrasive grains. Regarding the method.

〔従来の技術〕[Conventional technology]

従来、この種の電着工具の製造方法としては、例えば砥
石を成形する枠型の内面に砥粒を電着で固定する、いわ
ゆる逆電着砥石の製造法が公知である。
Conventionally, as a method for manufacturing this type of electrodeposition tool, for example, a method for manufacturing a so-called reverse electrodeposition grindstone is known, in which abrasive grains are fixed by electrodeposition on the inner surface of a frame for forming the grindstone.

すなわち、電着工具の砥面形状を成形する金属製または
カーボン製枠型の成形面(すなわち砥粒の頭を揃えて、
砥石の砥面を成形する面)に、予め接着剤を薄く塗布し
ておき、その成形面に砥粒を一層の厚さに整列密着させ
て接着し、次いで接着された砥粒を保持して強固に固定
するべくニッケル(Nt)めっきを所要の厚さに施して
砥粒を機械的に固定し、更に融点の低い焼結金属を溶融
したものを流しこんで固化させてベースを形成し、その
後に枠型を除去する。金属製枠型であれば切削して除去
し、カーボン製枠型であれば割って除去する。かくして
得られ電着工具の砥面には頭を揃えて密着配列されてい
る砥粒間を満たしてニッケル層が露出しているから、電
気分解によりそのニッケル層を砥粒径のおよそ3/10
までとり除き、完成品とする。
In other words, the forming surface of the metal or carbon frame mold that forms the abrasive surface shape of the electrodeposition tool (i.e., aligning the heads of the abrasive grains,
A thin layer of adhesive is applied in advance to the surface of the whetstone (the surface on which the abrasive surface is to be formed), and the abrasive grains are aligned and adhered to the molded surface in a layer of thickness, and then the bonded abrasive grains are held. In order to firmly fix the abrasive grains, nickel (Nt) plating is applied to the required thickness to mechanically fix the abrasive grains, and a molten sintered metal with a low melting point is poured in and solidified to form the base. Then remove the frame. If it is a metal frame, it is removed by cutting, and if it is a carbon frame, it is broken and removed. On the abrasive surface of the electrodeposition tool obtained in this way, a nickel layer is exposed filling the space between the abrasive grains, which are closely arranged with their heads aligned, so that the nickel layer is removed by electrolysis to approximately 3/10 of the abrasive grain diameter.
The finished product is then removed.

〔発明が解決しようとする課題〕[Problem to be solved by the invention]

しかしながら、上記従来の電着工具の製造方法には、次
のような問題点がある。
However, the above conventional method for manufacturing an electrodeposition tool has the following problems.

■ 枠型は、その成形面が、電着工具で加工される被加
工面の形状に合わせて高精度で仕上げ加工が施されてお
り、したがって高価であるにもかかわらず、ただ1度し
か使用できない。
■ The molding surface of the frame is finished with high precision to match the shape of the surface to be machined with the electrodeposition tool, and therefore, despite being expensive, it can only be used once. Can not.

■ 枠型を切削するか又は割って除去するため手間がか
かる。更には、枠型除去後に、砥面側で砥粒間を埋めて
いる電着めっき層を所定の厚さだけ除去するのに、電気
分解を利用しているため長時間を要する。
■ It takes time and effort to remove by cutting or breaking the frame. Furthermore, after the frame is removed, it takes a long time to remove a predetermined thickness of the electrodeposited layer filling the spaces between the abrasive grains on the abrasive surface side because electrolysis is used.

以上のことから、コスト高となり、且つ生産性が良くな
い。
For the above reasons, the cost is high and the productivity is not good.

そこで本発明は、上記従来の問題点を解決するためにな
されたものであり、枠型は除去が簡単で且つ再使用可能
であり、また砥面を電気分解で仕上げる必要もない、低
コストで生産性の高い電着工具の製造方法を提供するこ
とを目的とする。
Therefore, the present invention was made to solve the above-mentioned conventional problems, and the frame mold is easy to remove and can be reused, and there is no need to finish the abrasive surface by electrolysis, and it is low cost. The purpose of the present invention is to provide a method for manufacturing an electrodeposition tool with high productivity.

〔課題を解決するための手段〕[Means to solve the problem]

上記目的を達成する本発明の電着工具の製造方法は、枠
型の成形面に砥粒を整列密着せしめ、その砥粒をニッケ
ルメッキにより固定し、その後枠型を除去する。しかし
て、枠型の成形面に予め低融点金属の被膜を形成し、温
度を上げてその被膜を溶融した状態で砥粒を整列せしめ
、次いで温度を下げ溶融金属を固化せしめて砥粒を仮固
定し、その後に所要の厚みに二・ノケルメッキを施す工
程を含むものである。
The method for manufacturing an electrodeposition tool of the present invention which achieves the above object involves aligning and bringing abrasive grains into close contact with the molding surface of a frame, fixing the abrasive grains by nickel plating, and then removing the frame. Therefore, a coating of a low-melting metal is formed on the molding surface of the frame in advance, the temperature is raised to melt the coating, and the abrasive grains are aligned, and then the temperature is lowered to solidify the molten metal to temporarily form the abrasive grains. This process involves fixing the material and then applying Ni-Nokel plating to the required thickness.

〔作用] 枠型の成形面に予め形成した低融点金属の被膜を砥粒の
仮固定に用い、その後ニッケルメ・ンキで砥粒を本固定
するものであるから、枠型の除去に際しては、単に温度
を低融点金属の被膜の融点まで昇温しでやればよい。こ
れにより、枠型と砥粒との間に介在して砥粒を仮固定し
ていた被膜が溶融して流出し、枠型は簡単に抜き取るこ
とが可能である。そのため、枠型を従来のように切削し
たり割ったりして除去する必要はなく、繰り返し再使用
することができる。
[Function] Since the abrasive grains are temporarily fixed using a low-melting metal coating pre-formed on the molding surface of the frame mold, and then permanently fixed with nickel paint, when removing the frame mold, simply remove the abrasive grains. This can be done by raising the temperature to the melting point of the low melting point metal coating. As a result, the film interposed between the frame mold and the abrasive grains and temporarily fixing the abrasive grains melts and flows out, and the frame mold can be easily removed. Therefore, there is no need to remove the frame by cutting or breaking it as in the conventional case, and the frame can be reused repeatedly.

また、枠型を除去したあとで、適切な砥粒突出量を確保
するため、従来は砥粒間を埋めている砥面側のニッケル
メッキを電解を利用して所定量だけ取り除き砥面を仕上
げる必要があった。しかし、本発明にあっては、めっき
して予め形成される低融点金属の被膜の厚さを砥粒突出
量に見合う厚さに形成しておき、最後にその被膜を溶融
して除去すればよいから、砥面を設備費や処理時間のか
かる電気分解で仕上げる必要もない。
In addition, after removing the frame mold, in order to ensure an appropriate amount of abrasive grain protrusion, a predetermined amount of nickel plating on the abrasive surface side, which conventionally fills in between the abrasive grains, is removed using electrolysis to finish the abrasive surface. There was a need. However, in the present invention, the thickness of the low melting point metal film that is formed in advance by plating is formed to a thickness that corresponds to the amount of abrasive grain protrusion, and the film is finally melted and removed. Because of this, there is no need to finish the abrasive surface using electrolysis, which requires equipment costs and processing time.

かくして、低コストで且つ高生産性が得られる。In this way, low cost and high productivity can be obtained.

〔実施例〕〔Example〕

以下、本発明の実施例を図面を参照して説明する。第1
図(a)〜(樽は、本発明の第1の実施例を示す製造工
程図である。1は金属製の円筒状枠型で、その内径面が
成形面2になっている。このように成形面2が内面側の
場合は、除去の容易性の理由から、枠型1の金属材とし
ては線膨張係数がニッケルより大きいもの、例えば銅系
の合金が望ましい。
Embodiments of the present invention will be described below with reference to the drawings. 1st
Figures (a) to (barrel) are manufacturing process diagrams showing the first embodiment of the present invention. 1 is a metal cylindrical frame mold, the inner diameter surface of which is the molding surface 2. When the molding surface 2 is on the inner side, the metal material of the frame mold 1 is desirably a material having a coefficient of linear expansion larger than that of nickel, such as a copper-based alloy, for ease of removal.

先ず、この枠型1の成形面2に、鉛(pb)。First, lead (pb) is applied to the molding surface 2 of this frame mold 1.

錫(Sn)等の低融点金属からなる被膜3を、所定厚さ
にめっきして予め形成する(第1図う))。
A coating 3 made of a low melting point metal such as tin (Sn) is formed in advance by plating to a predetermined thickness (FIG. 1B)).

その被膜3が形成された成形面2に、ダイヤモンド、C
BN等の砥粒4を密着させて一層に並べて配置する。そ
の際、被膜3の低融点金属の融点まで温度を上げ、被膜
3を溶融状態にして砥粒4を整列させる。砥粒4は溶融
した低融点金属膜に食い込ませる。次いで温度を下げる
ことにより、溶融状態の低融点金属の被113を固化さ
せ、砥粒4を成形面2に仮固定して保持する(第1図(
C))。
On the molding surface 2 on which the coating 3 is formed, diamond, C
Abrasive grains 4 such as BN are arranged in a single layer in close contact with each other. At this time, the temperature is raised to the melting point of the low melting point metal of the coating 3 to melt the coating 3 and align the abrasive grains 4. The abrasive grains 4 are made to bite into the molten low melting point metal film. Next, by lowering the temperature, the molten low-melting point metal coating 113 is solidified, and the abrasive grains 4 are temporarily fixed and held on the molding surface 2 (see FIG.
C)).

この状態で、枠型1の内面側に所要の厚さにニッケルメ
ッキを施し、ニッケルめっき層5を形成する(第1図(
d))。第2図に拡大して示すように、ニッケルめっき
層5は被膜3に仮固定されている砥粒4の間隙に入り込
んで、砥粒4を本固定する。
In this state, nickel plating is applied to the inner surface of the frame 1 to a required thickness to form a nickel plating layer 5 (see Fig. 1).
d)). As shown in an enlarged view in FIG. 2, the nickel plating layer 5 enters the gap between the abrasive grains 4 temporarily fixed to the coating 3, and permanently fixes the abrasive grains 4.

ここで、上記低融点のめっき被膜3の厚さは、完成砥石
の砥面における砥粒突出量に見合う厚さに形成するのが
良い。最適な砥粒・突出量を得るためには、砥粒4の直
径の1/3程度とすることが好ましい。それを越えた厚
さになると、補強用のニッケルめっき層5が砥粒4を包
む厚さが砥粒4の2/3未満になり、薄過ぎて砥粒4を
保持する力が弱くなる。逆に、被膜3があまりに薄いと
、砥粒4を枠型の成形面2に固定保持することが困難に
なり無意味である。
Here, the thickness of the low melting point plating film 3 is preferably formed to a thickness commensurate with the amount of abrasive grain protrusion on the grinding surface of the finished grindstone. In order to obtain the optimum abrasive grain/protrusion amount, it is preferable that the diameter of the abrasive grain 4 is about 1/3. If the thickness exceeds this, the thickness with which the reinforcing nickel plating layer 5 wraps around the abrasive grains 4 becomes less than 2/3 of the abrasive grains 4, which is too thin and the strength to hold the abrasive grains 4 becomes weak. On the other hand, if the coating 3 is too thin, it becomes difficult to securely hold the abrasive grains 4 on the molding surface 2 of the frame, which is meaningless.

その後、砥粒4を仮固定している被膜3の融点まで温度
を上げて枠型1を除去する。その際、昇温で低融点の被
膜3が溶融すると共に、線膨張係数の大きい枠型1がニ
ッケルめっき層5より大きく熱膨張するから、枠型1は
容易に除去される。
Thereafter, the temperature is raised to the melting point of the coating 3 on which the abrasive grains 4 are temporarily fixed, and the frame 1 is removed. At this time, the coating 3 having a low melting point melts due to the temperature rise, and the frame 1 having a large coefficient of linear expansion thermally expands more than the nickel plating layer 5, so that the frame 1 is easily removed.

溶融した被膜3も流れて砥粒4から分離除去される。か
くして、肉厚のニッケルめっき層5の外面に砥粒4が粒
径の2/3程埋まって固着している中間品が得られる(
第1図(e))。
The melted coating 3 also flows and is separated and removed from the abrasive grains 4. In this way, an intermediate product is obtained in which the abrasive grains 4 are embedded and fixed to the outer surface of the thick nickel plating layer 5 by about 2/3 of the grain size (
Figure 1(e)).

この中間品の中心部に心金6を挿入して位置決めする(
第1図げ))。
Insert the mandrel 6 into the center of this intermediate product and position it (
Figure 1)).

最後に、その心金6とニッケルめっき層5との間の空間
部に、鉛や錫よりは高いが比較的融点の低い焼結金属合
金7を溶融させたものを流し込み、冷却固化させて電着
工具10が完成する(第1図(g))。
Finally, a molten sintered metal alloy 7, which has a higher melting point than lead or tin but has a relatively low melting point, is poured into the space between the core metal 6 and the nickel plating layer 5, and is cooled and solidified. The mounting tool 10 is completed (FIG. 1(g)).

上記の工程によれば、枠型1と砥粒4とは、低融点金属
の被膜3を介して接合されているに過ぎず、被膜3を溶
融させることにより切削したり割ったりすることなく簡
単に除去でき、元の形状・寸法が維持されるから、何度
でも再使用が可能である。
According to the above process, the frame mold 1 and the abrasive grains 4 are simply joined through the coating 3 of a low-melting point metal, and by melting the coating 3, it is easy to avoid cutting or breaking. Since it can be removed and its original shape and dimensions are maintained, it can be reused many times.

また、その除去に要する時間も極めて短時間で済む。Moreover, the time required for its removal can be extremely short.

また、完成した電着工具10の砥面10aの寸法精度は
、枠型1の除去のために切削されることがなく、成形面
2の精度がそのままに表れるから、制御が容易であり、
高精度のものが得やすい。
In addition, the dimensional accuracy of the abrasive surface 10a of the completed electrodeposition tool 10 is not cut to remove the frame 1, and the accuracy of the forming surface 2 appears as it is, so it is easy to control.
High precision is easy to obtain.

第3図に第2の実施例を示す。FIG. 3 shows a second embodiment.

この実施例の製造工程は、枠型1の内面側に所要の厚さ
にニッケルメッキを施し、ニッケルめっき層5を形成す
るまで(第3図(a)〜(d))は、上記第1の実施例
の第1図(a)〜(d)までと同様である。
The manufacturing process of this embodiment is to apply nickel plating to the required thickness on the inner surface of the frame 1 and to form the nickel plating layer 5 (FIGS. 3(a) to 3(d)). This is the same as in FIGS. 1(a) to 1(d) of the embodiment.

その後の工程がいくらか異なる。すなわち、本実施例の
場合は、枠型1を除去する前に、中心部に心金6を挿入
して位置決めする(第3図(C))。
The subsequent steps are somewhat different. That is, in the case of this embodiment, before removing the frame 1, the mandrel 6 is inserted into the center and positioned (FIG. 3(C)).

次に、その心金6とニッケルめっき層5との間の空間部
に、鉛や錫よりは高いが比較的融点の低い焼結金属合金
7を溶融させたものを流し込み、冷却固化させる(第3
図げ))。
Next, a molten sintered metal alloy 7, which has a higher melting point than lead or tin but has a relatively low melting point, is poured into the space between the core metal 6 and the nickel plating layer 5, and is cooled and solidified. 3
Figure)).

最後に、砥粒4を仮固定している被膜3の融点まで温度
を上げて枠型工を除去し、電着工具10が完成する(第
3図(6))。
Finally, the temperature is raised to the melting point of the coating 3 on which the abrasive grains 4 are temporarily fixed, and the frame molding is removed, completing the electrodeposition tool 10 (FIG. 3 (6)).

この実施例の作用・効果は上記第1の実施例の場合と同
様である。
The functions and effects of this embodiment are the same as those of the first embodiment.

なお、上記各実施例は、電着工具lOが円筒形砥石で、
その外面に砥面を有するものの製造工程を例示したが、
円筒形以外に例えば円板状の平面形砥石や、第4図に示
すような円錐形砥石や、第5図に示すような球面形砥石
であれば、オーバーハングとなる部分が無いかぎり、枠
型1の除去は円筒形砥石の場合より、容易である。
In addition, in each of the above embodiments, the electrodeposition tool IO is a cylindrical grindstone,
Although the manufacturing process of the product having an abrasive surface on its outer surface is illustrated,
In addition to the cylindrical shape, if there is a disc-shaped flat grindstone, a conical grindstone as shown in Fig. 4, or a spherical grindstone as shown in Fig. 5, the frame will fit as long as there is no overhang. Removal of mold 1 is easier than with a cylindrical grindstone.

第6図に示すような枠抜きの不可能な形状の曲面砥石(
例えば、玉軸受の外輪軌道面研磨用の砥石)の場合は、
枠型1として割り型を使用する。
A curved whetstone with a shape that makes it impossible to cut out the frame as shown in Figure 6 (
For example, in the case of a grindstone for polishing the outer raceway surface of ball bearings,
A split mold is used as frame mold 1.

また、円筒形砥石であって内面に砥面を有するものの場
合は、第7図に示すように、円柱状の枠型1の外面が成
形面2であり、その外面に低融点金属の被膜3を形成し
て砥粒4を仮固定し、更にその外径側にニッケルめっき
層5を形成することとなる。この場合の枠型1の材質と
しては、ニッケルより線膨張係数の小さな金属、例えば
鋳鉄にクロムめっきを施したものを使用して、枠型1の
除去を容易にする。
In addition, in the case of a cylindrical whetstone having an abrasive surface on the inner surface, as shown in FIG. is formed to temporarily fix the abrasive grains 4, and further a nickel plating layer 5 is formed on the outer diameter side thereof. In this case, the frame 1 is made of a metal having a coefficient of linear expansion smaller than nickel, such as cast iron plated with chromium, so that the frame 1 can be easily removed.

〔発明の効果〕〔Effect of the invention〕

以上説明したように、本発明によれば、枠型の成形面に
予め低融点金属の被膜を形成し、温度を上げてその被膜
を溶融した状態で砥粒を整列せしめ、次いで温度を下げ
溶融金属を固化せしめて砥粒を仮固定し、その後に所要
の厚みにニッケルメッキを施して砥粒を本固定し、枠型
を除去するものとした。そのため、枠型の成形面と砥粒
間に介在する低融点金属の被膜を溶融すれば、枠型は非
破壊で短時間に除去することができ、且つ繰り返し再使
用することができる。
As explained above, according to the present invention, a coating of a low-melting metal is formed on the molding surface of the frame in advance, the temperature is raised to melt the coating and the abrasive grains are aligned, and then the temperature is lowered and the coating is melted. The metal was solidified to temporarily fix the abrasive grains, then nickel plating was applied to the required thickness to permanently fix the abrasive grains, and the frame was removed. Therefore, by melting the low melting point metal coating interposed between the molding surface of the frame and the abrasive grains, the frame can be removed non-destructively in a short time and can be reused repeatedly.

また、低融点金属の被膜を溶かして枠型を除去すれば、
適切な砥粒突出量が確保できるから、更に砥面を仕上げ
加工する必要もない。
Also, if the frame is removed by melting the low melting point metal coating,
Since an appropriate amount of abrasive grain protrusion can be secured, there is no need to further finish the abrasive surface.

かくして、低コストで且つ高生産性の電着工具の製造方
法が提供できる。
Thus, a method for manufacturing an electrodeposition tool at low cost and high productivity can be provided.

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

第1図(a)ないしく匂は本発明の製造工程の一例を説
明する模式図、第2図は第1図(d)の要部拡大図、第
3図(a)ないしく濁は本発明の製造工程の他の例を説
明する模式図、第4図、第5図、第6図、第7図はそれ
ぞれ第1図に示す以外の他の電着工具形状の場合を説明
する模式図である。 1−・−枠型、2−・−成形面、3−(低融点金属の)
被膜、4−砥粒、5・・・ニッケルめっき層。
Figure 1 (a) or odor is a schematic diagram illustrating an example of the manufacturing process of the present invention, Figure 2 is an enlarged view of the main part of Figure 1 (d), and Figure 3 (a) or odor is a schematic diagram illustrating an example of the manufacturing process of the present invention. Schematic diagrams illustrating other examples of the manufacturing process of the invention, and Figures 4, 5, 6, and 7 are schematic diagrams illustrating cases of electrodeposition tool shapes other than those shown in Figure 1, respectively. It is a diagram. 1-.- Frame mold, 2-.- Molding surface, 3- (of low melting point metal)
coating, 4-abrasive grains, 5... nickel plating layer.

Claims (1)

【特許請求の範囲】[Claims] (1)枠型の成形面に砥粒を整列密着せしめ、該砥粒を
ニッケルメッキにより固定し、その後枠型を除去する電
着工具の製造方法において、 前記枠型の成形面に予め低融点金属の被膜を形成し、温
度を上げて前記被膜を溶融した状態で砥粒を整列せしめ
、次いで温度を下げ溶融金属を固化せしめて砥粒を仮固
定し、その後に所要の厚みにニッケルメッキを施す工程
を含むことを特徴をする電着工具の製造方法。
(1) In a method for producing an electrodeposition tool, in which abrasive grains are aligned and brought into close contact with the molding surface of a frame mold, the abrasive grains are fixed by nickel plating, and then the frame mold is removed, the molding surface of the frame mold is preliminarily coated with a low-melting-point powder. A metal film is formed, the temperature is raised to align the abrasive grains while the film is melted, the temperature is then lowered to solidify the molten metal and the abrasive grains are temporarily fixed, and then nickel plating is applied to the required thickness. 1. A method for manufacturing an electrodeposition tool, comprising the step of applying.
JP2243303A 1990-09-13 1990-09-13 Production of electrodeposition tool Pending JPH04124297A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP2243303A JPH04124297A (en) 1990-09-13 1990-09-13 Production of electrodeposition tool

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP2243303A JPH04124297A (en) 1990-09-13 1990-09-13 Production of electrodeposition tool

Publications (1)

Publication Number Publication Date
JPH04124297A true JPH04124297A (en) 1992-04-24

Family

ID=17101828

Family Applications (1)

Application Number Title Priority Date Filing Date
JP2243303A Pending JPH04124297A (en) 1990-09-13 1990-09-13 Production of electrodeposition tool

Country Status (1)

Country Link
JP (1) JPH04124297A (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105081993A (en) * 2015-07-16 2015-11-25 郑州磨料磨具磨削研究所有限公司 Resin-bonded cubic boron nitride (CBN) cut-in grinding wheel and manufacturing process thereof

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105081993A (en) * 2015-07-16 2015-11-25 郑州磨料磨具磨削研究所有限公司 Resin-bonded cubic boron nitride (CBN) cut-in grinding wheel and manufacturing process thereof

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