JP2005002392A - Electrode for discharging surface treatment and discharging surface treatment method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain an electrode for discharging surface treatment, which improves a denseness of a coating without causing the instability of discharge, and to provide a discharging surface treatment method. <P>SOLUTION: The discharging surface treatment comprises generating a pulsed discharge between the electrode of a green compact formed by compression-molding the powder of a metal or a metal compound, and a workpiece; and forming a coating consisting of an electrode material or a substance produced after the electrode material has been reacted by the discharging energy, on a workpiece surface. The electrode for the discharging surface treatment contains a material having a lower boiling point than that to be coated, as an additive. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

これらＮａやＫなどのアルカリ金属やＭｇなどのアルカリ土類金属，ＰやＳなどの非金属元素は、電極材料となるＦｅ（鉄：沸点２７５０℃）やＣｕ（銅：沸点２７５０℃）、Ｃｏ（コバルト：沸点３１００℃）の沸点の約１／３以下である。
そのため、上述したように、放電発生時の爆風の速度を上げ、電極材料をより高速にワークに対して供給することができる。
【００１５】
本発明の放電表面処理用電極製造プロセスを図２に示す。
平均粒径３μｍ以下の金属粉末またはセラミックス粉末に低沸点物質のＺｎ（亜鉛）の粉末を混合する。
【００１６】
放電表面処理において、放電を発生させるために電極とワークの間に印可される電圧は、８０Ｖ〜３００Ｖであり、この電圧印可させると、処理中の電極とワークの間は、０．３ｍｍ程度となる。
仮に、放電により離脱した電極材料の塊が、０．３ｍｍより大きくなると、極間を短絡させてしまうため、塊の大きさを０．３ｍｍ以下にするために、ふるいをかけることにより、凝集された塊が電極材料となることを防止するものである。なお、塊の大きさが０．３ｍｍ以下であれば、極間に０．３ｍｍ以下の塊が存在しても、次の放電を発生でき、放電は距離の近い箇所で発生するため、塊のあるところで放電が起こり、放電の熱エネルギーや爆発力で塊を細かく砕くことができるため、問題は少ない。
また、ふるいをかけ、バラバラにした電極材料は、次工程で行うワックスとの混合も十分に行え、電極の成形性向上の点でも有利である。
【００１７】
混合された粉末を金型に入れてパンチにより圧力をかけてプレスする際に、粉末内部へのプレス圧力の伝わりを良くするために粉末にパラフィンなどのワックスを重量比１％から１０％程度混入すると成形性を改善することができる。
しかしながら、パラフィンなどのワックスと混合すると粉末は再び液体が粉末の周りを液体が覆い、その分子間力や静電気力の作用により凝集し大きな塊を形成する。
そこで、再び凝集した塊をバラバラにするため、篩いにかける必要がる。
その方法は、前述と同様である。
仮に、篩の工程を省略すると、電極内に０．３ｍｍ以上の大きな塊が混在することになる。
また、粉砕工程を省略し、平均粒径数十μｍの粉末をそのまま使用しても電極を成形できるが、その電極は、表面の硬度が高く、中心部の硬度が低くなり、硬さのばらつきを持つ。
そのため、放電により中心部は消耗されるが、表面付近は消耗されず、堆積加工が進まなくなる。
すなわち、電極の外周部は硬いため、電極材料が供給されず、除去加工になるが、反対に電極の中心部は脆いため、処理開始後すぐに消耗される。
その結果、電極表面は、外周部が飛び出し、中心部がへこんだ形状となり、放電は、除去加工となる外周部のみで発生するようになり、堆積加工ができなくなる。
【００１８】
その後、所定のプレス圧を粉末にかけることで，粉末は固まり圧粉体となる。
そして、圧縮成形された圧粉体は，圧縮により所定の硬さが得られていればそのまま放電表面処理用の電極として使用することができるが，加熱することで強度を増すことができる。
加熱に関しては、得られた圧粉体を、真空炉または窒素雰囲気の炉で加熱して導電性を持つ圧粉体電極を製造する。
この際、電極中にあったワックスは加熱中に蒸発し，電極中から除去されている。
加熱温度を高くすると電極は硬くなり，加熱温度を低くすると電極は軟らかくなる。
また，電極材料の粉末の粒径が小さい場合には電極は硬くなり，粉末の粒径が大きい場合には電極は軟らかくなる。
なお、成形性の高い粉末を用いる場合は，ワックスを混入する必要はなく、ワックス混入後の篩工程を省略できる。
【００１９】
実施例
【００２０】
Ｃｏ（コバルト）粉末（３μｍ）にＺｎ粉末（１μｍ）を重量比で１０％混入させ，所定のプレス圧力で成形した後，真空炉で一時間加熱して電極を製造した。
電極の形状はφ１８×３０である。
そして、以上のような工程で製作されたＣｏ粉末からなる電極を用いて放電表面処理を行った。
使用した放電のパルス条件は、電極側マイナス、ワーク側プラスの極性、ピーク電流値ｉｅ＝５〜２０Ａ、放電持続時間（放電パルス幅）ｔｅ＝４〜１００μｓ程度で、５分間加工を行うことにより、緻密な被膜を形成することができた。
【００２１】
なお、本例では，粉末をＣｏ（３μｍ）としているが，平均粒径は３μｍ以下の範囲であればよい。
Ｚｎを混入させた電極を用いて形成された被膜の断面写真を図３に，混入させなかった電極を用いて形成されたの被膜の断面写真を図４に示す。
なお、両者の違いは、Ｚｎ混入の有無のみであり、電極製造、放電パルス条件は同一である。
図３と図４を比較すると，図３のほうに空孔が少ないことがわかる。
Ｚｎ以外に表１中の物質でも同様の効果を持つことはいうまでもない。
なお、電極材料に対する、低沸点物質の混入割合は、低沸点物質の混入が少なすぎると、放電による爆発力の向上に寄与せず、混入が多すぎると、該物質が被膜成分に含まれてしまうことから、被膜の性能を低下させることがあるため，例えば、１〜１０重量％が好ましく、その量は少ないほどよい。
【００２２】
本実施の形態によれば、低沸点の物質を放電表面処理用電極に混入したことにより、放電による爆風の速度を向上でき，溶融した粉末をワーク表面に高速で衝突させ，放電痕を扁平させることができ，より緻密な厚膜を形成することができる。
そして、このような緻密な被膜は、母材が雰囲気の気体や液体に曝させるのを防げるため，高温における耐酸化性被膜や耐コロージョン被膜のような用途に使用するのに最適である。
また、本実施の形態は、電極材料としてＣｏ粉末の場合について説明したが、これに限られるものではなく、Ｃｏ合金、Ｎｉ合金などに適用可能である。
なお、その際には、低沸点物質混入には、被膜の性能を低下させない程度で混入すればよい。
また、本実施の形態では、放電発生時の爆発速度（爆発力）が大きいため，大きな塊がワークに堆積したとしても，それを完全に分解でき，電極とワークの短絡を発生せず，安定した放電を得ることができる。
【００２３】
実施の形態２
本発明の放電表面処理用電極製造プロセスを図５に示す。
ここでは、平均粒径３μｍ以下の金属粉末に，火薬を十分に混合する。
なお、この工程で金属粉末と火薬の混合が十分でない場合、電極内で火薬の濃度に分布を生じてしまうので、電極と金属粉末は、密度差があるため、重力方向に粉末を攪拌することに特に注意する必要がある。
【００２４】
プレスの際に粉末内部へのプレス圧力の伝わりを良くするために粉末にパラフィンなどのワックスを重量比１％から１０％程度混入すると成形性を改善できるため、パラフィンなどのワックスと火薬と金属粉末の混合体（以下、混合体）とを混合する。
液体であるワックスと混合体を混合すると混合体は凝集し大きな塊を形成する。凝集した塊をバラバラにするために、メッシュサイズ０．３ｍｍ程度の網の上に置くことで篩いにかけ、凝集していない粉末、凝集した塊を分別する。
網の上に残った凝集した塊に対しては、セラミックス球または金属球を網の上に乗せ、網を振動させることにより、振動のエネルギーや球との衝突により凝集した塊がバラバラになり網を通過する。網を通過した粉末だけを次の工程で使用する。
【００２５】
その粉末を金型に入れてパンチにより上下から圧力をかけてプレスする。
所定のプレス圧を粉末にかけることで、粉末は固まり圧粉体となる。
圧縮成形された圧粉体は、その時点で所定の硬さ（圧縮強度で５０ＭＰａ程度）が得られていればそのまま放電表面処理用の電極として使用することができるが、加熱することで強度を増すことができる。
なお、ワックスを混入した場合でも、加熱することによりワックスは除去される。
【００２６】
本実施の形態で電極中に混入する火薬として，安全性の高いＡＮＦＯ（Ａｎｍｍｏｎｉｕｍ Ｆｕｅｌ Ｏｉｌ Ｅｘｐｌｏｓｉｖｅ）爆薬やスラリー爆薬が挙げられる。ＡＮＦＯ爆薬とは硝安油剤爆薬又は硝油爆薬のことで，プリル硝安９４％と軽油６％を混合して製造される。
このプリル硝安は、内部に空洞があり、表面に凹所の多い多孔性で油分を吸収しやすく加工された硝酸アンモニウムである。
スラリー爆薬は含水爆薬といい、原料として水を含有しているためこう呼ばれている。
標準的なものは硝酸アンモニウムを６０％ほどと２０％ほどの水を混合し、残りの割合はアルミニウム粉、モノメチルアミンナイトレート、エチレングリコールモノナイトレート、イソプロピルナイトレート、硝酸ヒドラジン、硫黄、パラフィンワックスなどの添加物、燃焼性物質をよく混ぜ合わせて製造される。
これらの火薬は，大気中で外から大きなエネルギーを吸収しなければ爆発を起こさない。
そのため，取り扱いが比較的容易である。
【００２７】
実施例
Ｃｏ粉末（１μｍ）にＡＮＦＯ爆薬を重量比５％混入させ，所定のプレス圧力で成形した後，真空炉で一時間加熱して電極を製造した。
電極の形状はφ１８×３０である。
そして、以上のような工程で製作されたＣｏ粉末からなる電極を用いて放電表面処理を行った。
使用した放電のパルス条件は、電極側マイナス、ワーク側プラスの極性、ピーク電流値ｉｅ＝５〜３０Ａ、放電持続時間（放電パルス幅）ｔｅ＝４〜１００μｓ程度で、５分間加工を行うことにより、緻密な被膜を形成することができた。
【００２８】
以上の条件により放電表面処理を行うと，ＡＮＦＯ爆薬の爆発のため，急激な体積膨張し，放電と同時に発生する爆風の速度が，飛躍的に増大する。
これは，同じ体積，温度，密度の気体を大きな袋と小さな袋の二つに押し込んで，それぞれを針で割ったときに発生する爆風の速度が，小さな袋（圧力が高い）ほうが速度が早くなるのに似た現象である。
その爆風に同伴される溶融粒子の速度は，向上する。
その上，爆発の熱により十分に溶融しないで被膜となっていた粒子を溶かすことができ，一つの放電痕を扁平化させる。その放電痕の積み重ねで被膜を形成するため，更に緻密な被膜を形成することができた。
【００２９】
本実施の形態では，火薬としてＡＮＦＯ爆薬について述べたが，スラリー爆薬も同様の効果を得ることができる。
なお、火薬の割合としては、１〜８％の範囲で入れればよく、５％が最適である。
また、被膜を形成する電極材料は、Ｃｏ合金やＮｉ合金に変更しても同様の効果を得ることができる。
【００３０】
本実施の形態によれば、ＡＮＦＯ爆薬，スラリー爆薬を放電表面処理用電極の電極材料として混入したことにより、放電により発生する爆風の速度を大きくでき，それに同伴される電極の溶融粒子の速度も向上でき，扁平化した放電痕を形成でき，緻密な被膜を形成できる。
更に，爆発時に発生する熱により溶融が不十分（粉末の中心まで溶けていなかった）であった電極粉を溶融でき，被膜の強度や緻密性を向上できる効果がある。また、放電発生時の爆発速度（爆発力）が大きいため，大きな塊がワークに堆積したとしても，それを完全に分解でき，電極とワークの短絡を発生せず，安定した放電を得ることができる。
【００３１】
【発明の効果】
本発明によれば、放電の不安定を発生させることなく，被膜の緻密性を向上させる放電表面処理用電極と放電表面処理方法を得ることができる。
【図面の簡単な説明】
【図１】放電表面処理の原理を示す図である。
【図２】電極製造工程を示す図である。
【図３】Ｚｎを混入させた電極を用いて形成された被膜の断面写真である。
【図４】Ｚｎを混入させなかった電極を用いて形成されたの被膜の断面写真である。
【図５】第二の実施の形態の電極製造工程を示す図である。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a green compact obtained by compression molding a metal powder or a metal compound powder, or a green compact obtained by heat-treating the green compact as an electrode, and a pulse between the electrode and the workpiece in the working fluid or in the air. This is related to a discharge surface treatment in which an electrode-like discharge is generated, and a film made of an electrode material or a substance obtained by reacting the electrode material with the discharge energy is formed on the work surface by the energy.
[0002]
[Prior art]
Surface treatment of aircraft gas turbine engine turbine blades, etc. requires coating or building up materials that have strength and lubricity in high temperature environments. Will occur.
In order to form such a film, it has been known that Cr (chromium) and Mo (molybdenum) in a high-temperature environment are oxidized to form an oxide, thereby exhibiting lubricity. Cobalt) is used as a base, and a material containing Cr or Mo is thickened by welding or thermal spraying.
Here, welding is a method in which the welding rod material is melted and adhered to the workpiece by electric discharge between the workpiece and the welding rod. Thermal spraying is a method in which a metal material is melted and sprayed onto the workpiece in a spray form. It is a method to make it.
[0003]
In thermal spraying, various efforts have been made to eliminate voids. In powder flame spraying, a method of accelerating with compressed air and a method of obtaining a high-speed combustion flame using fuel gas (kerosene, propylene, etc.) and oxygen are obtained. (HVOF) has been put into practical use.
The temperature of the combustion flame is the same as that of ordinary powder flame spraying (2500 ° C to 3000 ° C) or slightly lower, but the molten particle speed is more than 10 times, so it is very dense and has high adhesion. A film can be obtained.
[0004]
However, both the welding and thermal spraying methods are manual operations and require skill, so that it is difficult to line up the operations and there is a problem that costs increase.
In particular, welding is a method in which heat concentrates and enters the workpiece. Therefore, when processing thin materials, or in fragile materials such as directional control alloys such as single crystal and unidirectionally solidified alloys, weld cracking may occur. There is also a problem that the yield is low and the yield is low.
[0005]
On the other hand, although different from surface treatment methods such as welding and thermal spraying, which have strength and lubricity in a high temperature environment, other surface treatment techniques include, for example, electrical discharge machining as shown in International Publication WO99 / 47730. Surface treatment has also been established.
According to this method, a material that generates carbon by discharge energy, for example, an epoxy resin adhesive, is mixed into the electrode as a carbon supply source.
This material such as an epoxy adhesive is a material composed of carbon, hydrogen, oxygen, etc., which is decomposed by discharge energy, hydrogen atoms are mainly H ₂ O or hydrogen gas H ₂ , and oxygen atoms are water H ₂ O. or carbon dioxide CO _2, carbon atoms to carbon dioxide CO ₂ or carbon C.
Here, the produced carbon C is used when titanium Ti in the electrode reacts with titanium carbide TiC, and serves to form a hard coating.
In addition, when performing discharge surface treatment using an electrode mixed with other materials, the effect of increasing the film hardness by adding a material that generates carbon by discharge energy, such as an epoxy adhesive, is also recognized. Further, mixing paraffin or the like with the electrode is the same, and there is also an effect that the electrode can be firmly formed.
[0006]
[Reference Patent Document] International Publication No. WO99 / 47730
[Problems to be solved by the invention]
In recent years, there has been a demand not only for hard ceramic coatings intended for wear resistance at room temperature, but also for thick film formation of about 100 μm or more, using discharge surface treatment that can be lined without requiring manual labor. It is getting stronger.
As with the thermal spraying, the denseness of the coating is also a problem for the coating by the discharge surface treatment.
In the discharge surface treatment, a method has been proposed in which the open voltage is lowered to reduce the distance between the electrode and the workpiece in order to improve the film density.
When the distance between the electrode and the workpiece becomes small, the molten particles discharged from the electrode can reach the workpiece with almost no loss of speed.
However, since many particles detached from the electrode stay between the electrode and the workpiece (between the electrodes) during machining, if the distance between the electrodes is too small, a short circuit occurs due to these many particles, causing discharge. It becomes unstable and decreases the processing time and the surface accuracy of the coating.
For this reason, there is a limit to reducing the distance between the electrodes, and there is a problem that the denseness of the film cannot be further improved.
[0008]
An object of the present invention is to obtain a discharge surface treatment electrode and a discharge surface treatment method that improve the denseness of a coating without causing instability of discharge in the discharge surface treatment.
[0009]
[Means for Solving the Problems]
The discharge surface treatment electrode according to the present invention is a green compact obtained by compression molding a metal powder or a metal compound powder, or a green compact obtained by heat-treating the green compact as an electrode in a working fluid or in the air. In discharge surface treatment in which a pulsed discharge is generated between the electrode and the workpiece, and the energy is used to form a coating made of the electrode material or a material that reacts with the electrode material on the workpiece surface. A material having a boiling point is included as an additive.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
First, the principle of the discharge surface treatment is shown in FIG.
The electrode is made by compressing and molding a metal or metal compound powder of several μm, heat-treated, the electrode is the cathode, the workpiece is the anode, and the spindle is servoed so that they do not come in contact with each other. Electric discharge is generated between the electrode filled with the machining fluid and the workpiece.
A part of the workpiece and the electrode is melted and vaporized by the heat of discharge.
When the interparticle bonding force of the electrode is appropriate, a part of the electrode (molten particles) melted by the blast or electrostatic force from the discharge is pulled away from the electrode, moves toward the workpiece surface, and re-solidifies when it reaches the workpiece surface. It becomes a film.
[0011]
In the case of normal discharge surface treatment, the distance between the electrode and the workpiece is about 300 μm.
Molten particles that have jumped out of the electrode reach the workpiece while losing speed.
The higher the speed at which the molten particles reach, the more the particles are crushed and flattened, and the voids in the coating can be reduced.
However, conventional discharge surface-treated electrodes have strong electrode powder-to-powder bonding, so the electrodes have high thermal conductivity, heat can quickly move from the workpiece surface to the inside, and heat spots are difficult to form.
Therefore, the amount of electrode vaporization due to the heat of discharge (for example, 6000 ° C.) is small, and the speed of the blast generated along with the explosive vaporization is small.
Therefore, the speed at which the molten particles are transported from the electrode to the workpiece is reduced, and even when the molten particles reach the workpiece, the molten particles are not flattened, and the coating formed by repeating such discharge has many holes. .
[0012]
Therefore, in the present embodiment, the configuration of the electrode material is examined so that the electrode material pops out at a higher speed with vaporization due to heat at the time of occurrence of discharge.
That is, attention is paid to the vaporization of the substance accompanying heat, and an additive substance having a low boiling point (for example, a boiling point of 1/2 or less of the metal used as the coating) is mixed.
That is, the amount of vaporization of the low-boiling additive substance due to heat is increased to increase the speed of the blast (for example, several times), extrude the molten particles for forming the coating, and increase the arrival speed of the molten particles with respect to the workpiece Such a substance is added to the electrode material.
The molten particles are crushed into a flat shape, thereby densifying the coating.
[0013]
The phenomenon will be described in detail. Due to the occurrence of electric discharge, the electrode is a powder green compact, and the thermal conductivity is small. Therefore, the temperature at the point where the arc column and the electrode surface are in contact rises rapidly.
The metal powder that forms the coating only melts due to the heat, but the low-boiling substances around it can be instantly vaporized and expand from the electrode toward the workpiece.
The metal powder melted by the flow moves to the workpiece.
Here, the larger the amount (density) of the substance contained in the explosively expanding flow (blast), the higher the speed of the blast. In other words, the inclusion of low-boiling substances in the electrode can increase the density of the blast and increase its speed.
[0014]
Table 1 shows the boiling points of typical low-boiling substances.
[Table 1]

These alkali metals such as Na and K, alkaline earth metals such as Mg, and nonmetallic elements such as P and S are Fe (iron: boiling point 2750 ° C.), Cu (copper: boiling point 2750 ° C.), Co, which are electrode materials. It is about 1/3 or less of the boiling point of (cobalt: boiling point 3100 ° C.).
Therefore, as described above, the speed of the blast when the discharge is generated can be increased, and the electrode material can be supplied to the workpiece at a higher speed.
[0015]
The process for producing an electrode for discharge surface treatment of the present invention is shown in FIG.
A low boiling point Zn (zinc) powder is mixed with a metal powder or ceramic powder having an average particle size of 3 μm or less.
[0016]
In the discharge surface treatment, the voltage applied between the electrode and the workpiece to generate discharge is 80 V to 300 V. When this voltage is applied, the gap between the electrode being processed and the workpiece is about 0.3 mm. Become.
If the lump of electrode material separated by discharge becomes larger than 0.3 mm, the electrodes will be short-circuited, so that the lump size is reduced by sieving to make the lump size 0.3 mm or less. This prevents the lump from becoming an electrode material. In addition, if the size of the lump is 0.3 mm or less, even if a lump of 0.3 mm or less exists between the poles, the next discharge can be generated, and the discharge is generated at a short distance. There is little problem because a discharge occurs at a certain point and the lump can be crushed finely by the thermal energy and explosive force of the discharge.
In addition, the electrode material that has been sieved and separated can be sufficiently mixed with the wax to be used in the next step, which is advantageous in terms of improving the moldability of the electrode.
[0017]
When the mixed powder is put into a mold and pressed with a punch to press it, wax such as paraffin is mixed in the powder in a weight ratio of 1% to 10% in order to improve the transmission of the pressing pressure into the powder. Then, moldability can be improved.
However, when mixed with wax such as paraffin, the powder again has a liquid covering the powder, and the liquid is agglomerated by the action of intermolecular force or electrostatic force to form a large lump.
Therefore, in order to separate the aggregated mass again, it is necessary to pass through a sieve.
The method is the same as described above.
If the sieving step is omitted, a large lump of 0.3 mm or more is mixed in the electrode.
In addition, the electrode can be formed by omitting the pulverization step and using powder with an average particle size of several tens of μm as it is, but the electrode has a high surface hardness, a low central hardness, and a variation in hardness. have.
Therefore, although the central portion is consumed by the discharge, the vicinity of the surface is not consumed and the deposition processing does not proceed.
That is, since the outer peripheral portion of the electrode is hard, the electrode material is not supplied and is removed, but conversely, the central portion of the electrode is fragile and is consumed immediately after the processing is started.
As a result, the electrode surface has a shape in which the outer peripheral portion protrudes and the central portion is recessed, and electric discharge is generated only in the outer peripheral portion to be removed, so that the deposition processing cannot be performed.
[0018]
Thereafter, a predetermined pressing pressure is applied to the powder, whereby the powder is solidified and becomes a green compact.
The compressed green compact can be used as it is as an electrode for discharge surface treatment as long as a predetermined hardness is obtained by compression, but the strength can be increased by heating.
As for heating, the obtained green compact is heated in a vacuum furnace or a furnace in a nitrogen atmosphere to produce a green compact electrode having conductivity.
At this time, the wax existing in the electrode is evaporated during heating and removed from the electrode.
When the heating temperature is raised, the electrode becomes harder, and when the heating temperature is lowered, the electrode becomes softer.
In addition, when the particle size of the electrode material powder is small, the electrode becomes hard, and when the particle size of the powder is large, the electrode becomes soft.
In addition, when using powder with high moldability, it is not necessary to mix wax, and the sieving process after wax mixing can be omitted.
[0019]
Example [0020]
An electrode was manufactured by mixing 10% by weight of Zn powder (1 μm) with Co (cobalt) powder (3 μm), forming at a predetermined pressing pressure, and then heating in a vacuum furnace for 1 hour.
The shape of the electrode is φ18 × 30.
And the discharge surface treatment was performed using the electrode which consists of Co powder manufactured by the above processes.
The discharge pulse conditions used were: electrode side minus, workpiece side plus polarity, peak current value ie = 5 to 20 A, discharge duration (discharge pulse width) te = about 4 to 100 μs, and machining for 5 minutes. A dense film could be formed.
[0021]
In this example, the powder is Co (3 μm), but the average particle size may be in the range of 3 μm or less.
FIG. 3 shows a cross-sectional photograph of the film formed using the electrode mixed with Zn, and FIG. 4 shows a cross-sectional photograph of the film formed using the electrode not mixed.
The difference between the two is only the presence or absence of Zn contamination, and the electrode manufacturing and discharge pulse conditions are the same.
Comparing FIG. 3 and FIG. 4, it can be seen that there are fewer holes in FIG.
Needless to say, the substances in Table 1 other than Zn have the same effect.
Note that the mixing ratio of the low-boiling substance to the electrode material does not contribute to the improvement of explosive force due to discharge if the mixing of the low-boiling substance is too small, and if the mixing is excessive, the substance is included in the coating component. Therefore, for example, 1 to 10% by weight is preferable, and the smaller the amount, the better.
[0022]
According to the present embodiment, by mixing a low boiling point substance in the discharge surface treatment electrode, the speed of the blast due to the discharge can be improved, the molten powder is collided with the work surface at a high speed, and the discharge trace is flattened. And a denser thick film can be formed.
And since such a dense coating prevents the base material from being exposed to atmospheric gases and liquids, it is optimal for use in applications such as an oxidation-resistant coating and a corrosion-resistant coating at high temperatures.
In this embodiment, the case of Co powder as the electrode material has been described. However, the present invention is not limited to this, and can be applied to a Co alloy, a Ni alloy, or the like.
In this case, the low-boiling point substance may be mixed to such an extent that the performance of the coating is not deteriorated.
In this embodiment, since the explosion speed (explosive force) at the time of occurrence of discharge is large, even if a large lump accumulates on the workpiece, it can be completely disassembled, and no short circuit occurs between the electrode and the workpiece. Discharge can be obtained.
[0023]
Embodiment 2
FIG. 5 shows a process for producing an electrode for discharge surface treatment according to the present invention.
Here, explosives are sufficiently mixed with metal powder having an average particle size of 3 μm or less.
In addition, if the mixing of metal powder and explosives is not sufficient in this process, the concentration of explosives will be distributed within the electrode, so the electrode and metal powder have a density difference, so the powder should be stirred in the direction of gravity. Special attention should be paid to.
[0024]
In order to improve the transmission of the pressing pressure inside the powder during pressing, wax such as paraffin is mixed with the powder in a weight ratio of 1% to 10% to improve the moldability. Therefore, wax such as paraffin, explosives and metal powder. And a mixture (hereinafter referred to as a mixture).
When the mixture is mixed with wax, which is a liquid, the mixture aggregates and forms a large mass. In order to disaggregate the agglomerated mass, it is put on a net having a mesh size of about 0.3 mm and sieved to separate non-agglomerated powder and agglomerated mass.
For the agglomerated lump remaining on the net, a ceramic sphere or metal sphere is placed on the net and the net is vibrated, so that the agglomerated lump is separated by vibration energy and collision with the sphere. Pass through. Only the powder that has passed through the net is used in the next step.
[0025]
The powder is put into a mold and pressed from above and below with a punch.
By applying a predetermined pressing pressure to the powder, the powder becomes a solid and becomes a green compact.
The compressed green compact can be used as it is as an electrode for discharge surface treatment as long as it has a predetermined hardness (compressive strength of about 50 MPa) at that time. Can be increased.
Even when the wax is mixed, the wax is removed by heating.
[0026]
Examples of explosives mixed in the electrodes in this embodiment include highly safe ANFO (Ammonium Fuel Oil Explosive) explosives and slurry explosives. An ANFO explosive is a salt oil explosive or glass oil explosive, which is manufactured by mixing 94% prill ammonium sulfate and 6% light oil.
This prill ammonium nitrate is ammonium nitrate that has a cavity inside and is porous with many recesses on the surface and processed to easily absorb oil.
Slurry explosives are called hydrous explosives and are called this because they contain water as a raw material.
The standard one is ammonium nitrate mixed with about 60% and 20% water, the remaining proportion is aluminum powder, monomethylamine nitrate, ethylene glycol mononitrate, isopropyl nitrate, hydrazine nitrate, sulfur, paraffin wax, etc. It is manufactured by mixing well the additives and flammable substances.
These explosives do not explode unless they absorb large amounts of energy from outside in the atmosphere.
Therefore, handling is relatively easy.
[0027]
Example Co powder (1 μm) was mixed with ANFO explosive 5% by weight, molded at a predetermined press pressure, and then heated in a vacuum furnace for 1 hour to produce an electrode.
The shape of the electrode is φ18 × 30.
And the discharge surface treatment was performed using the electrode which consists of Co powder manufactured by the above processes.
The discharge pulse conditions used are: electrode side minus, workpiece side plus polarity, peak current value ie = 5 to 30 A, discharge duration (discharge pulse width) te = about 4 to 100 μs, and machining for 5 minutes. A dense film could be formed.
[0028]
When the discharge surface treatment is performed under the above conditions, the ANFO explosive explodes and the volume of the blast rapidly increases due to rapid volume expansion.
This is because the velocity of the blast generated when a gas of the same volume, temperature, and density is pushed into two bags, a large bag and a small bag, and each is divided by a needle, is faster with a smaller bag (higher pressure). It is a phenomenon similar to becoming.
The speed of the molten particles entrained by the blast increases.
In addition, particles that have become a coating can be melted without being sufficiently melted by the heat of explosion, and one discharge mark is flattened. Since the film was formed by stacking the discharge marks, a denser film could be formed.
[0029]
In the present embodiment, the ANFO explosive has been described as the explosive, but the slurry explosive can obtain the same effect.
In addition, what is necessary is just to put in the range of 1-8% as a ratio of an explosive, and 5% is optimal.
The same effect can be obtained even when the electrode material for forming the coating is changed to a Co alloy or Ni alloy.
[0030]
According to the present embodiment, the ANFO explosive and the slurry explosive are mixed as the electrode material of the electrode for the discharge surface treatment, so that the speed of the blast generated by the discharge can be increased, and the speed of the molten particles of the electrode accompanied by the blast is also increased. It can be improved, flattened discharge traces can be formed, and a dense film can be formed.
Furthermore, it is possible to melt the electrode powder that was insufficiently melted (not melted to the center of the powder) by the heat generated at the time of explosion, thereby improving the strength and compactness of the coating. In addition, since the explosion speed (explosive force) at the time of discharge generation is large, even if a large lump is deposited on the workpiece, it can be completely decomposed, and a stable discharge can be obtained without causing a short circuit between the electrode and the workpiece. it can.
[0031]
【The invention's effect】
According to the present invention, it is possible to obtain a discharge surface treatment electrode and a discharge surface treatment method that improve the denseness of a film without causing instability of discharge.
[Brief description of the drawings]
FIG. 1 is a diagram showing the principle of discharge surface treatment.
FIG. 2 is a diagram showing an electrode manufacturing process.
FIG. 3 is a cross-sectional photograph of a film formed using an electrode mixed with Zn.
FIG. 4 is a cross-sectional photograph of a film formed using an electrode into which Zn was not mixed.
FIG. 5 is a diagram showing an electrode manufacturing process according to a second embodiment.

Claims (7)

A pulsed discharge is generated between the workpiece and the green compact electrode formed by compression molding metal powder or metal compound powder, and the electrode material or electrode material reacts to the workpiece surface by the discharge energy. In discharge surface treatment to form a film made of material,
An electrode for discharge surface treatment comprising a material having a boiling point lower than that of a material to be a film as an additive. The electrode for discharge surface treatment according to claim 1, wherein the material having a low boiling point is Na, Mg, Zn, P, S, K. The discharge surface treatment electrode according to claim 1, wherein the substance having a low boiling point is mixed with about 1 to 10% by weight of the green compact electrode. Using a green compact obtained by compression-molding a metal powder or metal compound powder, or a green compact obtained by heat-treating the green compact as an electrode, a pulsed discharge is generated between the electrode and the workpiece in the working fluid or in the air. In the discharge surface treatment in which the electrode material or the electrode material is formed on the workpiece surface by the energy generated by the material,
An electrode for discharge surface treatment characterized by containing explosives as an additive separately from the material for the coating. The discharge surface treatment electrode according to claim 4, wherein the material of the explosive is an ANFO explosive or a slurry explosive. A pulsed discharge is generated between the workpiece and the green compact electrode formed by compression molding metal powder or metal compound powder, and the electrode material or electrode material reacts to the workpiece surface by the discharge energy. In discharge surface treatment to form a film made of material,
A discharge surface treatment method characterized in that a film is formed using an electrode containing a material having a boiling point lower than that of the material to be the film. A pulsed discharge is generated between the workpiece and the green compact electrode formed by compression molding metal powder or metal compound powder, and the electrode material or electrode material reacts to the workpiece surface by the discharge energy. In discharge surface treatment to form a film made of material,
A discharge surface treatment method characterized in that a film is formed using an electrode containing an explosive powder.

Images