JP3707490B2 - Method for producing iron-based powder mixture for powder metallurgy with excellent fluidity and stable apparent density - Google Patents

Description

本発明は、潤滑剤、黒鉛粉、銅粉等の添加物の偏析および発塵（ダスト）の発生が少なく、製造後の流動性の経時変化が少なく、流動性に優れ、とりわけ見掛け密度の変動が極めて小さい粉末冶金用鉄基粉末混合物の製造方法に関する。   The present invention has less segregation and dust generation of additives such as lubricants, graphite powder, copper powder, etc., little change in fluidity with time after production, excellent fluidity, especially fluctuation in apparent density The present invention relates to a method for producing an iron-based powder mixture for powder metallurgy that is extremely small.

粉末冶金用鉄基粉末混合物は、鉄粉に銅粉、黒鉛粉、燐化鉄粉などの合金粉末と、さらに必要に応じて切削性改善用粉末に加えて、ステアリン酸亜鉛、ステアリン酸アルミニウム、ステアリン酸鉛などの潤滑剤を混合して製造するのが一般的である。このような潤滑剤は金属粉末との混合性や焼結時の逸散性などから選択されている。     The iron-based powder mixture for powder metallurgy is composed of iron powder, alloy powder such as copper powder, graphite powder and iron phosphide powder, and, if necessary, powder for improving machinability, zinc stearate, aluminum stearate, In general, it is produced by mixing a lubricant such as lead stearate. Such a lubricant is selected based on the miscibility with the metal powder and the dissipation during sintering.

しかし、このような混合方法は以下のような欠点を持っている。先ず、混合法の大きな欠点は原料混合物が偏析を生ずることである。偏析について述べると、粉末混合物は大きさ、形状および密度の異なる粉末を含んでいるため、混合後の輸送、ホッパへの装入、払い出し、または成形処理などの際に、容易に偏析が生じてしまう。例えば、鉄基粉末と黒鉛粉との混合物は、トラック輸送中の振動によって、輸送容器内において偏析が起こり、黒鉛粉が浮かび上がることは良く知られている。また、ホッパに装入された黒鉛はホッパ内偏析のため、ホッパより排出する際、排出の初期、中期、終期でそれぞれ黒鉛粉の濃度が異なることも知られている。   However, such a mixing method has the following drawbacks. First, a major drawback of the mixing method is that the raw material mixture is segregated. Regarding segregation, the powder mixture contains powders of different sizes, shapes, and densities, so segregation easily occurs during transport, mixing into the hopper, dispensing, or molding. End up. For example, it is well known that a mixture of iron-based powder and graphite powder segregates in the transport container due to vibration during truck transportation, and the graphite powder rises. It is also known that the graphite charged in the hopper is segregated in the hopper, so that when it is discharged from the hopper, the concentration of the graphite powder is different at the initial stage, middle stage, and final stage.

これらの偏析によって製品は組成にばらつきを生じ、寸法変化および強度のばらつきが大きくなって、不良品の原因となる。   These segregations cause variations in the composition of the product, resulting in large dimensional changes and variations in strength, causing defective products.

また、黒鉛粉などはいずれも微粉末であるため、混合物の比表面積を増大させ、その結果、流動性が低下する。このような流動性の低下は、成形用金型への充填速度を低下させるため、圧粉体の生産速度を低下させてしまうという欠点もある。   Moreover, since graphite powder etc. are all fine powders, the specific surface area of a mixture is increased, As a result, fluidity | liquidity falls. Such a decrease in fluidity decreases the filling rate of the molding die, and thus has the disadvantage of reducing the green compact production rate.

このような粉末混合物の偏析を防止する技術として結合剤を用いる技術があるが、粉末混合物の偏析を充分に改善するように結合剤の添加量を増加させると、粉末混合物の流動性が低下する問題点がある。（例えば、特許文献１、２参照。）
また本発明者らは先において、金属石鹸又はワックスとオイルとの共溶融物を結合剤として用いる方法を提案した。これらは粉末混合物の偏析と発塵を格段に低減することができると共に、流動性を改善することができるものである。しかし、これらの方法では上述の偏析を防止する手段に起因して、粉末混合物の流動性が経時的に変化する問題があった（例えば、特許文献３、４参照。）。 There is a technique using a binder as a technique for preventing the segregation of the powder mixture, but if the amount of the binder added is increased so as to sufficiently improve the segregation of the powder mixture, the fluidity of the powder mixture decreases. There is a problem. (For example, see Patent Documents 1 and 2.)
The present inventors have previously proposed a method of using a metal soap or a co-melt of wax and oil as a binder. These can remarkably reduce segregation and dust generation of the powder mixture and improve fluidity. However, these methods have a problem that the fluidity of the powder mixture changes over time due to the above-described means for preventing segregation (see, for example, Patent Documents 3 and 4).

そこで、さらに本発明者らは提案したような、高融点のオイルと金属石鹸の共溶融物を結合剤に用いる方法を開発した。その技術は、共溶融物の経時変化が少なく、粉末混合物の流動性の経時的な変化が低減されるものである。しかし、その技術では常温では固体の高融点の飽和脂肪酸と金属石鹸とを鉄基粉末と混合するので、粉末混合物の見掛け密度が変化するという別の問題があった（例えば、特許文献５参照。）。   Therefore, the present inventors have further developed a method using a co-melt of a high melting point oil and a metal soap as a binder as proposed. The technique has little change with time of the co-melt and reduces the change with time of the fluidity of the powder mixture. However, this technique has another problem in that the apparent density of the powder mixture changes because a solid high-melting saturated fatty acid and metal soap are mixed with iron-based powder at room temperature (see, for example, Patent Document 5). ).

この問題を解決するため本発明者らは、鉄基粉末表面を脂肪酸で被覆した後、鉄基粉末表面に添加物を脂肪酸と金属石鹸との共溶融物で付着させ、さらにその外表面に金属石鹸を添加するという方法を提案した（例えば、特許文献６参照。）。
特開昭５６−１３６９０１号公報 特開昭５８−２８３２１号公報 特開平１−１６５７０１号公報 特開平２−４７２０１号公報 特開平２−５７６０２号公報 特開平３−１６２５０２号公報 In order to solve this problem, the present inventors coated the surface of the iron-based powder with a fatty acid, and then adhered the additive to the surface of the iron-based powder with a co-melt of a fatty acid and a metal soap, and further coated a metal on the outer surface. A method of adding soap was proposed (see, for example, Patent Document 6).
JP-A-56-136901 JP 58-28321 A JP-A-1-165701 JP-A-2-47201 Japanese Patent Laid-Open No. 2-57602 JP-A-3-162502

これらの方法において偏析、発塵および流動性の問題はかなり解決したが、流動性に優れ、見掛け密度の変動、とりわけ外気温度および湿度に対する変動の問題に関してはいまだ不十分であった。すなわち、外気温度が１５℃と３５℃とでは見掛け密度の差は０．１ｇ／ｃｍ^３ 以上となるので、成形時、金型内への鉄粉の充填量が一定にならないため焼結体重量のばらつきとなり、ひいては焼結体の特性変動の原因となるため、これの解決が課題となっていた。 In these methods, the problems of segregation, dust generation and fluidity were considerably solved, but the fluidity was excellent, and the problem of fluctuations in apparent density, particularly fluctuations in ambient temperature and humidity, was still insufficient. That is, since the difference in apparent density between the outside air temperature of 15 ° C. and 35 ° C. is 0.1 g / cm ³ or more, the amount of iron powder in the mold is not constant during molding, so the weight of the sintered body As a result, this causes fluctuations in the characteristics of the sintered body.

本発明はこの課題を解決することを目的とするものである。本発明者らはこの課題解決のため鋭意検討を重ねた結果、鉄基粉末混合物の見掛け密度が鉄粉と潤滑剤の間の接触電位による静電気力に支配されるとの知見を得た。この知見に基づきさらに検討を加え、鉄基粉末混合物に帯電防止剤を添加すことにより温度、湿度が変わっても帯電量が一定となり、流動性が向上し、ホッパからの流出が円滑となり、見掛け密度の変動が小さくなることを発見し、本発明を完成するに到ったものである。   The present invention aims to solve this problem. As a result of intensive studies for solving this problem, the present inventors have obtained the knowledge that the apparent density of the iron-based powder mixture is governed by the electrostatic force due to the contact potential between the iron powder and the lubricant. Based on this knowledge, further investigations were made, and by adding an antistatic agent to the iron-based powder mixture, the amount of charge became constant even when the temperature and humidity changed, fluidity improved, smooth outflow from the hopper, and apparent appearance. The inventors have discovered that the fluctuation of density is small and have completed the present invention.

すなわち本発明は、基本的には０．００１〜０．１重量％の帯電防止剤を含むことを特徴とする流動性に優れ見掛け密度の安定な粉末冶金用鉄基粉末混合物であって、実質的には鉄基粉末に合金粉末、潤滑剤を混合してなる粉末冶金用鉄基粉末混合物において、さらに０．００１〜０．１重量％の帯電防止剤を含む流動性に優れ見掛け密度の安定な粉末冶金用鉄基粉末混合物の製造方法である。 That is, the present invention is basically an iron-based powder mixture for powder metallurgy having excellent fluidity and stable apparent density, characterized by containing 0.001 to 0.1% by weight of an antistatic agent, Specifically, in iron-based powder mixture for powder metallurgy, which is a mixture of iron-based powder and alloy powder and lubricant, it has excellent fluidity including 0.001-0.1% by weight of antistatic agent and stable apparent density. This is a method for producing an iron-based powder mixture for powder metallurgy.

本発明の粉末冶金用鉄基粉末混合物の他の製造方法として、鉄基粉末に、少なくとも１種以上の合金用粉末と融点の異なる２種以上のワックスを加えて１次混合し、１次混合工程中又は１次混合後に昇温してワックスの部分溶融物を生成させ、次いで２次混合しながら冷却し、前記部分溶融物を冷却固着させ、部分溶融物の結合力により鉄基粉末粒子の表面に合金用粉末を固着させ、さらに冷却時に金属石鹸又はワックスと、鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を加えて３次混合することを特徴とする見掛け密度の安定な粉末冶金用鉄基粉末混合物の製造方法を提案する。この方法において、３次混合の前に帯電防止剤を加えるのではなく、あらかじめ鉄基粉末表面に鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を付着させた鉄基粉末を用いてもよく、また、前記方法において、前記金属石鹸又はワックスと、帯電防止剤を加えて３次混合するに代えて、金属石鹸又はワックスを加えて３次混合後、鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を加えて４次混合することとしてもよい。 As another manufacturing method of the iron-based powder mixture for powder metallurgy according to the present invention, at least one kind of alloy powder and at least two kinds of waxes having different melting points are added to the iron-based powder, followed by primary mixing. During the process or after the primary mixing, the temperature is raised to form a partial melt of wax, and then cooled with secondary mixing, the partial melt is cooled and fixed, and the iron-based powder particles are bonded by the binding force of the partial melt. The alloy powder is fixed on the surface, and further, when cooled, metal soap or wax and 0.001 to 0.1 % by weight of an antistatic agent with respect to 100% by weight of the iron-based powder mixture are added and thirdarily mixed. A method for producing a characteristic iron-base powder mixture for powder metallurgy with stable apparent density is proposed. In this method, the antistatic agent is not added before the tertiary mixing, but 0.001 to 0.1 % by weight of the antistatic agent is attached to the surface of the iron- based powder beforehand with respect to 100% by weight of the iron-based powder mixture. may be used iron-based powder is also in the method, the metal soap or wax, in place of the mixed tertiary added antistatic agent, tertiary mixing after adding metallic soap or wax In addition, 0.001 to 0.1 % by weight of an antistatic agent may be added to 100% by weight of the iron-based powder mixture, and quaternary mixing may be performed.

また、鉄粉としては実質的な純鉄粉、プレアロイ合金粉、部分合金化粉（拡散付着粉）のいずれも適用可能である。   Further, as the iron powder, any of substantially pure iron powder, pre-alloy alloy powder, and partially alloyed powder (diffusion adhesion powder) can be applied.

これら本発明の粉末冶金用鉄基粉末混合物およびその製造方法において使用する帯電防止剤としては、アルキル基の炭素数が１０〜２０であるアルキルジメチルアミンオキサイド、アルキルジメチルアミノ酢酸ベタイン、アルキルカルボキシメチル−Ｎ−ヒドロキシエチルイミダソリニウムベタイン、アルキルアミドプロピルベタインから選ばれる１種、ＨＬＢ（親水性親油性バランス）が１〜１０のソルビタン脂肪酸エステル、ＨＬＢが９〜１５のポリエキシエチレンソルビタンモノ脂肪酸エステル、ＨＬＢが９〜１５のポリエキシエチレンアルキルエーテル、ＨＬＢが５〜１５のポリエキシエチレンアルキルフェニルエーテル、アルキル基の炭素数が１０〜２０のアルキルアルカノールアミドないしアルキル基の炭素数が１０〜２０のポリオキシエチレンアルキルアミンが好適である。特にアルキル基の炭素数が１０〜２０のアルキルカルボキシルメチル−Ｎ−ヒドロキシエチルイミダソリニウムベタイン、ＨＬＢ９〜１５のポリオキシエチレンアルキルエーテル及びアルキル基の炭素液が１０〜２０のポリオキシエチレンアルキルアミンが一層好適である。具体的な化合物例の一部を実施例において述べる。   Examples of the antistatic agent used in the iron-based powder mixture for powder metallurgy according to the present invention and the production method thereof include alkyldimethylamine oxide, alkyldimethylaminoacetic acid betaine, alkylcarboxymethyl- 1 type selected from N-hydroxyethyl imidazolinium betaine and alkylamidopropyl betaine, HLB (hydrophilic lipophilic balance) 1-10 sorbitan fatty acid ester, HLB 9-15 polyexethylene sorbitan monofatty acid ester , Polyethyleneethylene alkyl ether having an HLB of 9 to 15, polyoxyethylene alkyl phenyl ether having an HLB of 5 to 15, an alkyl alkanolamide having an alkyl group of 10 to 20 carbon atoms or an alkyl group having 10 to 20 carbon atoms Po Polyoxyethylene alkyl amines are preferred. In particular, alkylcarboxylmethyl-N-hydroxyethylimidazolinium betaine having 10 to 20 carbon atoms in the alkyl group, polyoxyethylene alkyl ether having 9 to 15 HLB, and polyoxyethylene alkylamine having 10 to 20 carbon atoms in the alkyl group. Is more preferred. Some specific compound examples are described in the Examples.

本発明によれば、添加物の偏析および発塵（ダスト）の発生が少なく、流動性の経時変化が少なく、見掛け密度の変動が極めて小さい粉末冶金用鉄基粉末混合物を得ることができる。とくに、見掛け密度の変動、とりわけ外気温度および湿度に対する変動の問題に関して、外気温度が１５℃と３５℃とでは見掛け密度の差は０．１Ｍｇ／ｍ^３ 以上であったものを０．０４Ｍｇ／ｍ^３ とすることができ、成形時、金型内への鉄粉の充填量を均一化し、焼結体重量のばらつきをなくしは焼結体の特性変動を防止することができるようになった。 According to the present invention, it is possible to obtain an iron-based powder mixture for powder metallurgy with little segregation of additive and generation of dust (dust), little change in fluidity with time, and extremely small change in apparent density. In particular, regarding the problem of fluctuations in apparent density, especially fluctuations with respect to the outside air temperature and humidity, the difference in the apparent density between the outside air temperature of 15 ° C. and 35 ° C. was 0.1 Mg / m ³ or more. ³ , the amount of iron powder filled in the mold can be made uniform at the time of molding, variation in the weight of the sintered body can be eliminated, and fluctuations in the characteristics of the sintered body can be prevented.

前述のように、流動性（ホッパからの流出性）及び鉄基混合粉末の見掛け密度は外気温度および湿度の変化に対応して変動し、成形時、金型内への鉄粉の充填量が一定にならないため焼結体重量のばらつきとなり、ひいては焼結体の特性変動の原因となるという問題を有していた。鉄基粉末混合物における見掛け密度の変動は、鉄粉と潤滑剤の間の接触電位による静電気力に支配されることを知見した結果、鉄基粉末混合物に帯電防止剤を添加することにより、流動性が向上し鉄基粉末の帯電量一定とすることで温度、湿度が変わっても見掛け密度の変動を小さくし得ることを発見したことも前述のとおりである。   As described above, the fluidity (flowability from the hopper) and the apparent density of the iron-based mixed powder fluctuate in response to changes in the outside air temperature and humidity. During molding, the amount of iron powder filling the mold is Since it is not constant, there is a problem that the weight of the sintered body varies, which in turn causes fluctuations in the characteristics of the sintered body. As a result of finding that the fluctuation of the apparent density in the iron-based powder mixture is governed by the electrostatic force due to the contact potential between the iron powder and the lubricant, the flowability can be improved by adding an antistatic agent to the iron-based powder mixture. As described above, it has been found that the variation in apparent density can be reduced even when the temperature and humidity are changed by making the charge amount of the iron-based powder constant.

帯電防止剤の作用については未だ不明確なことが多いが、以下のように考えられる。   The action of the antistatic agent is still often unclear, but is considered as follows.

すなわち、帯電防止剤は、鉄基粉末表面に吸着すると、温度、湿度が変動しても、鉄基粉末の表面に吸着された帯電防止剤がほぼ一定の水分量を吸着するため帯電量が小さくなり、ほぼ一定に保たれる。また、この吸着水分による静電気力、分子間力の低下により流動性も向上する。   That is, when the antistatic agent is adsorbed on the surface of the iron-based powder, the amount of charge is small because the antistatic agent adsorbed on the surface of the iron-based powder adsorbs a substantially constant amount of water even if the temperature and humidity fluctuate. And kept almost constant. In addition, the fluidity is improved due to the decrease in electrostatic force and intermolecular force due to the adsorbed moisture.

これらの帯電防止効果を有する帯電防止剤として使用できるものは前述の通り各種あるが、基本的に鉄基粉末の帯電を押えるものであればよい。しかしながら帯電を押えて見掛け密度の変動を小さくするには０．００１重量％以上の添加が必要であり、０．００１重量％未満であると効果を発揮しない。また、添加量が０．１重量％を超えてもその帯電防止効果は増加せず、むしろ粉末混合物の流動性を低下させるので好ましくない。したがって、帯電防止剤の添加量は鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％とすべきである。 There are various types of antistatic agents that can be used for these antistatic effects, as described above, but basically, any antistatic agent that can suppress the charging of the iron-based powder may be used. However, addition of 0.001% by weight or more is necessary to suppress the change in the apparent density by suppressing charging, and if it is less than 0.001% by weight, the effect is not exhibited. Further, even if the addition amount exceeds 0.1% by weight, the antistatic effect does not increase, but rather the fluidity of the powder mixture is lowered, which is not preferable. Therefore, the addition amount of the antistatic agent should be 0.001 to 0.1 % by weight with respect to 100% by weight of the iron-based powder mixture .

帯電防止剤を含む見掛け密度が安定した鉄基粉末混合物において、鉄基粉末と合金粉末や銅粉を固着する有機物（いわゆる潤滑剤）としては脂肪酸と金属石鹸との共溶融物または融点の異なる２種以上のワックスの部分溶融物であることが好ましい。本発明者らが特願平３−１６２５０２号公報で開示した脂肪酸と金属石鹸との共溶融物を用いる方法は、共溶融状態において融体が毛細管現象により添加物粒全体をコーティングし、鉄基粉末に強固に付着させるので最適である。融点の異なる２種以上のワックスの部分溶融物も同様な理由により好ましい。すなわち、具体的な製造方法として、鉄基粉末に常温で液体の脂肪酸を加えて１次混合し、次いで少なくとも１種以上の合金用粉末と金属石鹸とを加えて２次混合し、該２次混合工程中又は２次混合後に昇温して脂肪酸と金属石鹸の共溶融物を生成させ、次いで３次混合しながら冷却して前記共溶融物を冷却固着させ、該共溶融物の結合力により鉄基粉末粒子の表面に合金用粉末を固着させ、さらに冷却時に金属石鹸又はワックスと、鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を加えて４次混合する方法が好ましい。 In an iron-based powder mixture containing an antistatic agent and having a stable apparent density, an organic substance (so-called lubricant) that fixes the iron-based powder and the alloy powder or copper powder is a co-melt of fatty acid and metal soap or a different melting point 2 It is preferably a partial melt of more than one type of wax. In the method using the co-melt of fatty acid and metal soap disclosed in Japanese Patent Application No. 3-162502 disclosed by the present inventors, the melt coats the entire additive grain by capillary action in the co-melt state, It is optimal because it adheres firmly to the powder. A partial melt of two or more waxes having different melting points is also preferable for the same reason. That is, as a specific manufacturing method, a liquid fatty acid is added to iron-based powder at room temperature and mixed first, then at least one kind of alloy powder and metal soap are added and mixed secondarily. During the mixing step or after the secondary mixing, the temperature is raised to produce a co-melt of fatty acid and metal soap, and then cooled with tertiary mixing to cool and fix the co-melt, and due to the cohesive strength of the co-melt The powder for the alloy is fixed to the surface of the iron-based powder particles, and further, a metal soap or wax and 0.001 to 0.1 % by weight of an antistatic agent are added to 100% by weight of the iron-based powder mixture during cooling. A method of subsequent mixing is preferred.

なお、この方法において、前記金属石鹸又はワックスと、帯電防止剤を加えて４次混合することに代えて、金属石鹸又はワックスを加えて４次混合後、鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を加えて５次混合することとしてもよく、また、前記４次混合の前に帯電防止剤を加えるのではなく、あらかじめ鉄基粉末表面に鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を付着させた鉄基粉末を用いても同様な効果が得られる。 Incidentally, in this method, the metal soap or wax, in place of mixing quartic added antistatic agent, after four primary mixing by adding a metal soap or wax, the iron-based powder mixture 100 wt% relative It is also possible to add 0.001 to 0.1% by weight of an antistatic agent and mix the mixture in a fifth order. In addition, the antistatic agent is not added before the fourth mixing, but the iron-based powder surface is preliminarily added. The same effect can be obtained by using an iron-based powder having 0.001 to 0.1 % by weight of an antistatic agent attached to 100% by weight of the iron-based powder mixture .

また、鉄基粉末に、少なくとも１種以上の合金用粉末との融点の異なる２種以上のワックスを加えて１次混合し、該１次混合工程中又は１次混合後に昇温してワックスの部分溶融物を生成させ、ついで２次混合しながら冷却し、前記部分溶融物を冷却固着させ、該部分溶融物の結合力により鉄基粉末粒子の表面に合金用粉末を固着させ、さらに冷却時に金属石鹸又はワックスと、鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を加えて３次混合する方法も可能である。この方法において、３次混合の前に帯電防止剤を加えるのではなく、あらかじめ鉄基粉末表面に鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を付着させた鉄基粉末を用いてもよいのは前述と同様である。前記金属石鹸又はワックスと、帯電防止剤を加えて３次混合するに代えて、金属石鹸又はワックスを加えて３次混合後、鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を加えて４次混合することとしてもよい。 In addition, at least one wax having a melting point different from that of at least one kind of alloy powder is added to the iron-based powder and primary mixed, and the temperature of the wax is increased during the primary mixing step or after the primary mixing. A partial melt is formed, and then cooled with secondary mixing, the partial melt is cooled and fixed, and the alloy powder is fixed to the surface of the iron-based powder particles by the binding force of the partial melt. A method in which 0.001 to 0.1 % by weight of an antistatic agent is added to a metal soap or wax and 100% by weight of the iron-based powder mixture and tertiary mixing is also possible. In this method, the antistatic agent is not added before the tertiary mixing, but 0.001 to 0.1 % by weight of the antistatic agent is attached to the surface of the iron- based powder beforehand with respect to 100% by weight of the iron-based powder mixture. The iron-based powder made to be used may be the same as described above. The metal soap or wax, in place of the mixed tertiary added antistatic agent, after three primary mixing by adding a metal soap or wax, relative to the iron-based powder mixture 100 wt% 0.001 to 0. It is good also as quaternary mixing by adding 1 weight% of antistatic agent.

また鉄基粉末に予め帯電防止剤を付着させたのち潤滑剤、１種以上の合金粉末とＶブレンダーなどで単純混合してもよい。あるいは鉄基粉末に帯電防止材、潤滑剤、１種以上の合金粉末をＶブレンダーなどで単純混合してもよい。   Alternatively, an antistatic agent may be attached in advance to the iron-based powder, and then simply mixed with a lubricant, one or more alloy powders, and a V blender. Alternatively, an antistatic material, a lubricant, and one or more alloy powders may be simply mixed with the iron-based powder using a V blender or the like.

実施例１
表１〜３に示す帯電防止剤を平均粒径が７８μｍの粉末冶金用鉄粉にスプレー噴霧し３分間均一混合後、さらに平均粒径が２３μｍの天然黒鉛１重量％、ステアリン酸亜鉛０．７５重量％、平均粒径２５μｍの銅粉を２重量％添加混合後Ｖブレンダーで１５分混合した。これを混合方法１とする。 Example 1
The antistatic agent shown in Tables 1 to 3 was sprayed onto iron powder for powder metallurgy having an average particle size of 78 μm, mixed uniformly for 3 minutes, and further 1% by weight of natural graphite having an average particle size of 23 μm and zinc stearate 0.75. 2% by weight of copper powder having an average particle size of 25 μm was added and mixed, and then mixed with a V blender for 15 minutes. This is referred to as mixing method 1.

平均粒径が７８μｍの粉末冶金用鉄粉にオレイン酸を０．３％をスプレー噴霧し３分間均一混合した（１次混合）。その後平均粒径が２３μｍの天然黒鉛１重量％、ステアリン酸亜鉛０．４重量％、平均粒径２５μｍの銅粉を重量％添加混合後、十分に混合後、１１０℃で混合加熱し（２次混合）、さらに混合しながら８５℃以下に冷却して鉄粉粒子に黒鉛粉と銅分をオレイン酸とステアリン酸亜鉛の共溶融物結合材によって固着した粉末混合物を製造した（３次混合）。さらにステアリン酸亜鉛０．３重量％と表１に示す帯電防止剤を添加し均一に混合後加熱混合機から排出した（４次混合）。これを混合方法２とする。   An iron powder for powder metallurgy having an average particle size of 78 μm was sprayed with 0.3% of oleic acid and uniformly mixed for 3 minutes (primary mixing). Thereafter, 1% by weight of natural graphite having an average particle diameter of 23 μm, 0.4% by weight of zinc stearate, and copper powder having an average particle diameter of 25 μm are added and mixed, and after sufficient mixing, mixed and heated at 110 ° C. (secondary The mixture was further cooled to 85 ° C. or lower while mixing to produce a powder mixture in which graphite powder and copper content were fixed to iron powder particles with a co-melt binder of oleic acid and zinc stearate (tertiary mixing). Furthermore, 0.3% by weight of zinc stearate and the antistatic agent shown in Table 1 were added and mixed uniformly, and then discharged from the heating mixer (quaternary mixing). This is referred to as mixing method 2.

表１〜３に示す帯電防止剤を平均粒径が７８μｍの粉末冶金用鉄粉にスプレー噴霧し３分間均一混合後さらにオレイン酸を０．３％をスプレー噴霧し３分間均一混合した（１次混合）。その後平均粒径が２３μｍの天然黒鉛１重量％、ステアリン酸亜鉛０．４重量％、平均粒径２５μｍの銅粉を２重量％添加混合後、十分混合後、１１０℃で混合加熱し（３次混合）、さらに混合しながら８５℃以下に冷却して鉄粉粒子に黒鉛粉と銅粉をオレイン酸とステアリン酸亜鉛の共溶融物結合材によって固着した粉末混合物を製造した（３次混合）。さらにステアリン酸亜鉛０．３重量％添加し均一に混合後加熱混合機から排出した（４次混合）。これを混合方法３とする。   The antistatic agents shown in Tables 1 to 3 were spray-sprayed on iron powder for powder metallurgy having an average particle diameter of 78 μm and mixed uniformly for 3 minutes, and then 0.3% of oleic acid was spray-sprayed and uniformly mixed for 3 minutes (primary mixture). Then, after adding 1% by weight of natural graphite having an average particle size of 23 μm, 0.4% by weight of zinc stearate and 2% by weight of copper powder having an average particle size of 25 μm, mixing and heating at 110 ° C. (3rd order) The mixture was further cooled to 85 ° C. or lower while mixing to produce a powder mixture in which graphite powder and copper powder were fixed to iron powder particles with a co-melt binder of oleic acid and zinc stearate (tertiary mixing). Further, 0.3% by weight of zinc stearate was added and mixed uniformly, and then discharged from the heating mixer (quaternary mixing). This is referred to as mixing method 3.

平均粒径が７８μｍの粉末冶金用鉄粉に平均粒径が２３μｍの天然黒鉛粉１重量％、ステアリン酸アミドとエチレンビスステアリン酸アミドの混合物０．４重量％、平均粒径２５μｍの電解銅粉を２重量％添加混合後、十分混合後１１０℃で混合加熱し（１次混合）、さらに混合しながら８５℃以下に冷却して鉄粉粒子に黒鉛粉と銅粉を各々ステアリン酸アミドとエチレンビスステアリン酸アミドの共溶融物結合材によって固着した粉末混合物を製造した（２次混合）。さらにエチレンビスステアリン酸アミド０．３重量％とステアリン酸亜鉛０．１重量％と表１〜３に示す帯電防止剤を添加し均一に混合後加熱混合機から排出した（３次混合）。これを混合方法４とする。   1% by weight of natural graphite powder having an average particle size of 23 μm, 0.4% by weight of a mixture of stearamide and ethylenebisstearic acid, iron powder for powder metallurgy having an average particle size of 78 μm, electrolytic copper powder having an average particle size of 25 μm 2% by weight, mixed and heated sufficiently at 110 ° C. (primary mixing), and further cooled to 85 ° C. or lower while mixing to convert graphite powder and copper powder into stearate amide and ethylene, respectively. A powder mixture fixed by a bis-stearic acid amide co-melt binder was prepared (secondary mixing). Further, 0.3% by weight of ethylenebisstearic acid amide and 0.1% by weight of zinc stearate and the antistatic agents shown in Tables 1 to 3 were added and mixed uniformly, and then discharged from the heating mixer (tertiary mixing). This is referred to as mixing method 4.

表１〜３に示す帯電防止剤を平均粒径が７８μｍの粉末冶金用鉄粉にスプレー噴霧し３分間均一混合後、平均粒径が２３μｍの天然黒鉛粉１重量％、ステアリン酸アミドとエチレンビスステアリン酸アミドの混合物０．４重量％、平均粒径２５μｍの電解銅粉を２重量％添加混合後、十分混合後１１０℃で混合加熱し（１次混合）、さらに混合しながら８５℃以下に冷却して鉄粉粒子に黒鉛粉と銅粉を各々ステアリン酸アミドとエチレンビスステアリン酸アミドの共溶融物結合材によって固着した粉末混合物を製造した（２次混合）。さらにエチレンビスステアリン酸アミド０．３重量％とステアリン酸亜鉛０．１重量％を添加し均一に混合後加熱混合機から排出した（３次混合）。これを混合方法５とする。   After spraying the antistatic agent shown in Tables 1-3 on iron powder for powder metallurgy having an average particle size of 78 μm and uniformly mixing for 3 minutes, 1% by weight of natural graphite powder having an average particle size of 23 μm, stearic acid amide and ethylene bis Add 0.4% by weight of stearamide mixture and 2% by weight of electrolytic copper powder with an average particle size of 25 μm. Mix well, then mix and heat at 110 ° C. (primary mixing). The mixture was cooled to produce a powder mixture in which graphite powder and copper powder were fixed to iron powder particles by a co-melt binder of stearamide and ethylene bis stearamide, respectively (secondary mixing). Further, 0.3% by weight of ethylenebisstearic acid amide and 0.1% by weight of zinc stearate were added and mixed uniformly, and then discharged from the heating mixer (tertiary mixing). This is referred to as mixing method 5.

得られた混合粉１００ｇを相対湿度５０％のもと１５℃、３５℃の各条件で８時間保管後、２５℃相対湿度５０％の条件で素早く見掛け密度および流動度を測定した。見掛け密度の温度に対する変化率を、３５℃での見掛け密度と１５℃での見掛け密度との差で示し、見掛け密度の安定性の指標とした。   100 g of the obtained mixed powder was stored at 15 ° C. and 35 ° C. for 8 hours under a relative humidity of 50%, and then the apparent density and fluidity were quickly measured under the condition of 25 ° C. and 50% relative humidity. The change rate of the apparent density with respect to the temperature was shown by the difference between the apparent density at 35 ° C. and the apparent density at 15 ° C., and was used as an index of the apparent density stability.

実施例１〜実施例１１に示すように鉄基粉末混合物１００重量％に対して帯電防止剤０．００１〜０．１重量％を混合方法１乃至混合方法５により添加すれば見掛け密度安定性すなわち３５℃での見掛け密度と１５℃での見掛け密度との差が０．０４Ｍｇ／ｍ³以下と安定化することがわかる。比較例１〜比較例３は帯電防止剤を添加しない例であるが見掛け密度安定性すなわち３５℃での見掛け密度と１５℃での見掛け密度との差は０．１Ｍｇ／ｍ³を超え、本実施例の２．５倍から３倍程度に見掛け密度が変化する。比較例４〜比較例６では、帯電防止剤の添加量が少ない場合であり見掛け密度の安定性に劣り、また比較例７〜比較例９のように帯電防止剤が０．１重量％を超えると流動度が低下する。なお参考例１０〜参考例２３に示すように帯電防止剤のアルキル基の炭素数あるいはＨＬＢによっては、見掛け密度安定性の改善効果が小さく、流動性の低下が目立つものや、見掛け密度の安定性に効果の少ないものがあり、帯電防止剤の選択に注意が必要である。 As shown in Examples 1 to 11, if 0.001 to 0.1% by weight of an antistatic agent is added by mixing method 1 to mixing method 5 with respect to 100% by weight of the iron-based powder mixture, apparent density stability, that is, It can be seen that the difference between the apparent density at 35 ° C. and the apparent density at 15 ° C. is stabilized at 0.04 Mg / m ³ or less. Comparative Examples 1 to 3 are examples in which no antistatic agent is added, but the apparent density stability, that is, the difference between the apparent density at 35 ° C. and the apparent density at 15 ° C. exceeds 0.1 Mg / m ^3. The apparent density changes from 2.5 times to 3 times of the embodiment. In Comparative Examples 4 to 6, the addition amount of the antistatic agent is small and the apparent density is inferior, and the antistatic agent exceeds 0.1% by weight as in Comparative Examples 7 to 9. And fluidity decreases. As shown in Reference Examples 10 to 23, depending on the number of carbon atoms or HLB of the alkyl group of the antistatic agent, the effect of improving the apparent density stability is small, the decrease in fluidity is conspicuous, or the apparent density is stable. Some of them have little effect, and care must be taken in selecting an antistatic agent.

実施例２
平均粒径が７８μｍの粉末冶金用鉄粉に平均粒径が２３μｍの天然黒鉛粉１重量％、ステアリン酸アミドとエチレンビスステアリン酸アミドの混合物０．４重量％、平均粒径２５μｍの電解銅粉を２重量％添加混合後、十分混合後１１０℃で混合加熱し（１次混合）、さらに混合しながら８５℃以下に冷却して鉄粉粒子に黒鉛粉と銅粉を各々ステアリン酸アミドとエチレンビスステアリン酸アミドの部分溶融物結合材によって固着した粉末混合物を製造した（２次混合）。さらにエチレンビスステアリン酸アミド０．３重量％とステアリン酸亜鉛０．１重量％と表４に示す帯電防止剤を添加し均一に混合後、加熱混合機から排出した（３次混合）。これを混合方法Ａとする。 Example 2
1% by weight of natural graphite powder having an average particle size of 23 μm, 0.4% by weight of a mixture of stearamide and ethylenebisstearic acid, iron powder for powder metallurgy having an average particle size of 78 μm, electrolytic copper powder having an average particle size of 25 μm 2% by weight, mixed and heated sufficiently at 110 ° C. (primary mixing), and further cooled to 85 ° C. or lower while mixing to convert graphite powder and copper powder into stearate amide and ethylene, respectively. A powder mixture fixed by a bisstearic acid partial melt binder was prepared (secondary mixing). Further, 0.3% by weight of ethylenebisstearic acid amide and 0.1% by weight of zinc stearate and the antistatic agent shown in Table 4 were added and mixed uniformly, and then discharged from the heating mixer (tertiary mixing). This is referred to as mixing method A.

表４に示す帯電防止材を平均粒径が７８μｍの粉末冶金用鉄粉にスプレー噴霧し３分間均一混合後、平均粒径が２３μｍの天然黒鉛粉１重量％、ステアリン酸アミドとエチレンビスステアリン酸アミドの混合物０．４重量％、平均粒径２５μｍの電解を２重量％添加混合後、十分混合後１１０℃で混合加熱し（１次混合）、さらに混合しながら８５℃以下に冷却して鉄粉粒子に黒鉛粉とを各々ステアリン酸アミドとエチレンビスステアリン酸アミドの部分溶融物結合材によって固着した粉末混合物を製造した（２次混合）。さらにエチレンビスステアリン酸アミド０．３重量％とステアリン酸亜鉛０．１重量％を添加し均一に混合後、加熱混合機から排出した（３次混合）。これを混合方法Ｂとする。   After spraying the antistatic material shown in Table 4 onto iron powder for powder metallurgy having an average particle size of 78 μm and uniformly mixing for 3 minutes, 1% by weight of natural graphite powder having an average particle size of 23 μm, stearamide and ethylenebisstearic acid After adding and mixing 2% by weight of an amide mixture of 0.4% by weight and an average particle size of 25 μm, the mixture was thoroughly mixed and heated at 110 ° C. (primary mixing), and further cooled to 85 ° C. or lower while mixing. A powder mixture was produced in which graphite powder was fixed to the powder particles with a partial melt binder of stearamide and ethylene bis stearamide, respectively (secondary mixing). Further, 0.3% by weight of ethylenebisstearic acid amide and 0.1% by weight of zinc stearate were added and mixed uniformly, and then discharged from the heating mixer (tertiary mixing). This is referred to as mixing method B.

平均粒径が７８μｍの粉末冶金用鉄粉に平均粒径が２３μｍの天然黒鉛粉１重量％、ステアリン酸アミドとエチレンビスステアリン酸アミドの混合物０．４重量％、平均粒径２５μｍの電解を２重量％に添加混合後、十分混合後１１０℃で混合加熱し（１次混合）、さらに混合しながら８５℃以下に冷却して鉄粉粒子に黒鉛粉とを各々ステアリン酸アミドとエチレンビスステアリン酸アミドの共融物結合材によって固着した粉末混合物を製造した（２次混合）。さらにエチレンビスステアリン酸アミド０．３重量％とステアリン酸亜鉛０．１重量％添加し、均一に混合後、加熱混合機から排出した（３次混合）。排出後さらに表４に示す帯電防止剤を添加し混合した（４次混合）。これを混合方法Ｃとする。   1% by weight of natural graphite powder having an average particle size of 23 μm, 0.4% by weight of a mixture of stearamide and ethylenebisstearic acid, and 2 μm of electrolysis having an average particle size of 25 μm are applied to iron powder for powder metallurgy having an average particle size of 78 μm. After adding and mixing to wt%, mixing well and mixing and heating at 110 ° C. (primary mixing), further cooling to 85 ° C. or lower while mixing, and iron powder particles into stearamide and ethylenebisstearic acid, respectively. A powder mixture fixed with an amide eutectic binder was prepared (secondary mixing). Further, 0.3% by weight of ethylenebisstearic acid amide and 0.1% by weight of zinc stearate were added, mixed uniformly, and then discharged from a heating mixer (tertiary mixing). After discharging, antistatic agents shown in Table 4 were further added and mixed (quaternary mixing). This is referred to as mixing method C.

ホッパ流出性（流動性）は、内径１００ｍｍ、高さ２００ｍｍの容器に混合粉末を１ｋｇ装入し、容器中央に設けた直径２ｍｍのオリフィスから混合物を流出させた。流出しない場合は容器の上部を直径３ｍｍ、長さ５０ｍｍの丸棒にて加振し、流出する間での加振回数をホッパ叩き回数と称し、ホッパ流出性（流動性）の指標とした。   As for the hopper flowability (fluidity), 1 kg of mixed powder was charged into a container having an inner diameter of 100 mm and a height of 200 mm, and the mixture was discharged from an orifice having a diameter of 2 mm provided in the center of the container. When it did not flow out, the upper part of the container was vibrated with a round bar having a diameter of 3 mm and a length of 50 mm, and the number of times of vibration during outflow was referred to as the number of times the hopper was struck.

表４に示すように、帯電防止剤を０．００１〜０．１重量％を、混合方法Ａ、Ｂ、Ｃのいずれの方法で添加しても、ホッパ叩き回数は１回以下であった。帯電防止剤を用いない場合のホッパ叩き回数は６回であり、ホッパ流出性の格段の改善が達成された。また比較例に示すように帯電防止剤の添加量が０．１重量％を越えた場合、あるいは０．０１重量％未満ではホッパ流出性が劣化する。   As shown in Table 4, even when 0.001 to 0.1% by weight of the antistatic agent was added by any of the mixing methods A, B, and C, the number of times the hopper was hit was 1 or less. When the antistatic agent was not used, the number of hits with the hopper was 6 times, and a marked improvement in the hopper flowability was achieved. Further, as shown in the comparative example, when the addition amount of the antistatic agent exceeds 0.1% by weight or less than 0.01% by weight, the hopper outflow property is deteriorated.

Claims (3)

鉄基粉末に、少なくとも１種以上の合金用粉末と融点の異なる２種以上のワックスを加えて１次混合し、該１次混合工程中又は１次混合後に昇温してワックスの部分溶融物を生成させ、次いで２次混合しながら冷却し、前記部分溶融物を冷却固着させ、該部分溶融物の結合力により鉄基粉末粒子の表面に合金用粉末を固着させ、さらに冷却時に金属石鹸又はワックスと、鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を加えて３次混合することを特徴とする流動性に優れ見掛け密度の安定な粉末冶金用鉄基粉末混合物の製造方法。 Two or more kinds of waxes having different melting points from at least one kind of alloy powder are added to the iron-based powder, followed by primary mixing, and the temperature is raised during or after the primary mixing to partially melt the wax. And then cooling with secondary mixing, the partial melt is cooled and fixed, the alloying powder is fixed to the surface of the iron-based powder particles by the binding force of the partial melt, and further the metal soap or For powder metallurgy with excellent fluidity and stable apparent density, characterized by adding 0.001 to 0.1 % by weight of an antistatic agent to 100% by weight of wax and an iron-based powder mixture, and then performing tertiary mixing A method for producing an iron-based powder mixture. 請求項１記載の方法において、前記金属石鹸又はワックスと、帯電防止剤を加えて３次混合することに代えて、金属石鹸又はワックスを加えて３次混合後、鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を加えて４次混合することを特徴とする流動性に優れ見掛け密度の安定な粉末冶金用鉄基粉末混合物の製造方法。 The method of claim 1, wherein the metal soap or wax, in place of mixing the tertiary added antistatic agent, after three primary mixing by adding a metal soap or wax, the iron-based powder mixture 100 wt% A method for producing an iron-based powder mixture for powder metallurgy having excellent fluidity and stable apparent density , wherein 0.001 to 0.1% by weight of an antistatic agent is added to quaternary mixing. 請求項１記載の方法において、前記３次混合前に帯電防止剤を加えることに代えて、予め鉄基粉末表面に鉄基粉末混合物１００重量％に対して０．００１〜０．１重量％の帯電防止剤を付着させた後、該鉄基粉末に、少なくとも１種以上の合金用粉末と融点の異なる２種以上のワックスを加えて１次混合することを特徴とする流動性に優れ見掛け密度の安定な粉末冶金用鉄基粉末混合物の製造方法。 The method according to claim 1, wherein, instead of adding an antistatic agent before the tertiary mixing, 0.001 to 0.1 % by weight of 100% by weight of the iron-based powder mixture on the surface of the iron- based powder in advance. After the antistatic agent is deposited, the iron-based powder is mixed with at least one kind of alloy powder and at least two kinds of waxes having different melting points, and is first mixed, and has excellent fluidity and apparent density. Of stable iron-based powder mixture for powder metallurgy.