瑞典专利SE1350599A1 Mixed powder for powder metallurgy and process for preparing the same

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SUMMARY A formulation for preparing a mixed powder for powder metallurgy which can prevent graphite segregation and which has sufficient flowability and achieves precise lubricating properties, the process comprising: selecting an organic binder when the presence of an organic lubricant at a given temperature of an organic lubricant. beddrns be 1, has an axis of 2 or higher yid the given temperature the given discharge medium; mixing the organic lubricant and the organic binder with the given organic solvent together with an iron powder to produce an iron powder slurry which the organic lubricant and the organic binder have loaded onto the organic solvent; and removing the organic solvent from the iron powder slurry by drying to precipitate the organic lubricant and the organic binder in this order.
公开号:SE1350599A1
申请号:SE1350599
申请日:2011-11-14
公开日:2013-07-04
发明作者:Hironori Suzuki；Shinya Arima
申请人:Kobe Steel Ltd；
IPC主号:

专利说明:

Patent literature 1: JP-A No. S60 (1985) -502158 Patent literature 2: JP-A No. H6 (1994) -49503 Patent literature 3: JP-A No. H5 (1993) -86403 Patent literature 4: JP-A No. H7 (1995) DESCRIPTION OF THE INVENTION The problem that the invention intends to solve Due to the situation described above, an object of the present invention is to provide: a mixed powder for powder metallurgy which has good flowability. and narrow formSga; and a method of making the ground powder.
A manufacturing process according to the present invention which lasers the above-mentioned problems comprises the processes of: selecting an organic binder which, when the solubility of an organic lubricant at a given temperature a given organic solvent is determined to be 1, has an insolvency of 2 ever hagre at the given temperature the given solvent; mixing the organic lubricant and the organic binder with the given organic solvent together with an Orn powder to produce an iron powder storage medium in which the organic lubricant and the organic binder are dissolved in the organic solvent; and removing the organic solvent from the iron powder slurry by a process for precipitating the organic lubricant and the organic film in this order, a production process according to the present invention is preferred that, when the ratio of the solubility of the organic binder to the solubility of the organic solvent ) is represented by a, the quantity of the organic lubricant is less than 100 xa per 100 parts by weight of the organic lubricant.
It is preferred that: the organic solvent is an organic solvent of the aromatic hydrocarbons; the organic binder is a fatty acid ester represented by the structural expression (1) below; and the organic lubricant is a fatty acid amide represented by the structural expression (2) below. More preferably, the fatty acid amyl is hexadecaric acid amide, (N-octadecenyl) bexadecaric acid amide ever (1 1-octadecyl) docosenoic acid amide.
R1C00-CH2-0--12-000R2 (1) .R4 (2) (in the terms R1 and R2 represent aliphatic piston groups which are identical to or different from each other, R3 represents an aliphatic piston group and R4 represents a hydrogen atom or a piston group) .
Furthermore, it is preferred that the iron powder slurry further contain a high molecular weight antistatic agent and it is further preferred that the high molecular weight antistatic agent be: a copolymer of styrene and synthetic rubber containing 5 parts by weight of 95 parts by weight of styrene and 95 parts by weight; or a hydride thereof.
The present invention comprises a mixed powder for powder metallurgy obtained by the above manufacturing method. The presently dangerous invention further comprises a blended powder for powder metallurgy, wherein a yam powder is charged with an organic lubricant and an organic binder. It is preferred that the proportion of the organic lubricant be greater on the outside than on the outer side of the coating layer with which the iron powder is coated. The Effect of the Invention The manufacturing process of the present invention comprises a mixed powder for powder metallurgy, wherein an iron powder is charged with an organic lubricant and an organic binder; and to provide both flowability and srnorjfOrmaga to the blended powder for powder metallurgy. Furthermore, when graphite is used in a deposition process in accordance with the present invention, it is necessary to prevent the graphite from segregating.
BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a graph showing the solubility of hexadecarboxylic acid amide and the solubility and solubility of ethylene glycol toluene stearic acid diester.
Hg. 2 is a flow chart showing the experimental procedure an example described later.
Hg. and (ii) selecting the organic binder and the organic lubricant so that the solubilities thereof differ significantly from each other in a given organic welding agent and the solubility of the organic binder component may be higher than that of the organic lubricant. By doing this, it is possible to charge the iron powder with both the organic lubricant and the organic binder and obtain both the properties of lubricant color and flowability. Furthermore, in addition to the organic lubricant and the organic binder used in the present invention, the properties of smOgiformaga and flowability, respectively, Oiler that an organic material having a higher solubility ailmarget exhibits a better effect in improving flowability, thus precipitating the organic binder which has a high solubility, and thus has a good flowability, according to the present invention, and consequently the flowability of the mixed powder can be maximized.
However, when a mixed powder for powder metallurgy according to the present invention contains such a graphite, both the organic binder and the organic lubricant, according to the present invention, function as a binder, and thus segregation of the graphite can also be prevented by their existence. Srharjfarrn6ga, In this context ,: the magnitude of the friction when a shaped body Jr is produced by forming a mixed powder with a mold and the shaped body is extracted before the mold; and can be evaluated, for example, with an exhaust pressure which will be shown in an example described later. Contemporary, flowability: meant the rarity of a mixed puiver; and can be evaluated, for example, by a flowability and a critical discharge diameter shown in an example DESCRIBED later.
An organic lubricant and an organic binder are selected in the following manner. That is, a combination is such that, according to an organic solvent used, when the solubility of an organic lubricant is considered to be 1 at a given temperature, the solubility of an organic binder may be 2 or higher at the same given temperature. If a given temperature can be set within the temperature range used when an organic lubricant and an organic binder agent are mixed with a used organic solvent and dissolved.
Organic lasers are classified into an alcoholic system, an ester system, an ether system, an amide system, a ketone system, an aromatic hydrocarbon system, an aliphatic hydrocarbon system, etc.
As the organic lasers of the alcohol system, methanol, ethanol, propanol, butanol, etc. are mentioned, for example. As the ester sister's organic release component 5, for example, ethyl acetate, butyl acetate, etc. are named. As the organic solvent of the ether system, dimethyl ether, methyl ethyl ether, tetrahydrofuran, ethylene glycol dimethyl ether, etc. are exemplified, for example. As the organic solvents of the amide cysteine, for example, dimethylformamide, dirnetylacetamide, acetanilide, etc. are named. The organic lasers of the ketone system are, for example, acetone, methyl ethyl ketone, etc. named. As organic aromatics of the aromatic carbonate system, benzene, toluene, xylene, etc. are named in particular. The organic solvents of the aliphatic carbonate system are, for example, hexane, heptane, etc. A preferred organic solvent is an organic solvent component of an aromatic hydrocarbon system, otherwise known as toluene. In the present invention, an organic release agent and an organic binder are selected to meet the hazardous composition of the said compound. In accordance with the type of organic release agent, the agent is specified as follows. A preferred organic barrier agent is a fatty acid ester, represented by the term (1) shown below, named and, as a preferred organic lubricant, a fatty acid amide, represented by the term (2) shown below, is named.
R1C00-012-012-000R2 (1) (2) (In the terms R 1 and R 2 represent all-phase piston groups which are identical to or different from each other, R 3 represents enaliphatic piston group, and R 4 represents a water tower at all a piston group).
A fatty acid ester represented by the expression (1) may be formally considered as a substance obtained by the esterification of ethylene glycol and a type of fatty acid, but may be a substance co-produced by another method. Sam R 1 and R 2 are a saturated piston group (alkyl group) and an unsaturated piston group (alkenyl group or alkynyl group) named. The number of unsaturated obstacles of a reacted piston group may be either one or a plurality (for example about 2 to 6, more preferably about 2 to 3). Each of R 1 and R 2 is preferably an alkyl group and now an alkyl group having a calant number of 12 ever more. If a carbon number is 11 or less, a fatty acid ester (diester) represented by the expression (1) is a state of a wash or a semi-solid bone (fat) and the flowability is increased.
Sam and R 2k are, for example, matted carbonate groups including a tridecyl group, a tetradecyl group, a pentadekyl group, a hexadecyl group, a heptadekyl group, an actadekyl group, a nonadekyl group, an icosyl group, a docosyl group, a tetracosyl group, a hexacosyl group, a triacontyl group, an octaconyl group, unsaturated piston groups including an octadesylidene group, a cosylidene group, etc., named. Each of R 1 and R 2 is preferably an octacyl cooling group and the Pada fatty acids include moiety and R 2, respectively, are preferably stearic acid.
A fatty acid amide represented by the expression (2) may be formally considered as a dehydrated product of R 3 COOH and R 4 NH 2, but may be a substance prepared by another method. S3 R3 is, like R1 ever R2, a saturated piston group (alkyl group) and an unsaturated piston group (alkenyl group ever alkynyl group) named. The number of unsaturated obstacles an unsaturated piston group may be either one or four (for example about 2 to 6, preferably around 2 to 3). R 3 is typically an alkyl group or an alkenyl group. The carbonate group is thirdly the state of a straight chain but can also be formed by replacing a carbon atom forming a straight chain (main chain) with one or more lower alkyl groups (for example alkyl groups each having a number of carbon atoms of 1 to 6, in particular about 1 to 3). The number of carbon atoms of a piston group is three times not less than 8 to not more than 24, the case of replacement with an alkyl group is for example the number of carbon atoms of the main chain not less than 5 to not more than 26. R4 may be selected from the range corresponding to R3 and may otherwise be a vat atom. R 4 is, thereto, an alkyl group, an alkenyl group, or a hydrogen atom.
When R 3 is an alkyl group, for example an octyl group, a nonyl group, a clekyl group, an undecyl group, a dodecyl group, a tridecyl group, a tetradekyl group, a pentadekyl group, a hexadecyl group, a heptadekyl group, an octadecyl group, a nonadekyl group, an henosyl group, an henosyl group, a docosyl group, a tricosyl group, a tetracosyl, etc. named. R 3 is thirdly a hexadecyl group and, preferably a fatty acid comprising R 3, is hexacecanoic acid named.
When R 3 is an alkenyl group is, for example, an octylidene group, a nonylidene group, a decylidene group, a undecylidene group, a dodecylidene group, a tridecylidene group, a tetradekylidene group, a pentadekylidene group, a hexadekylidene group, a heptadekylidene group, a docidene, an octidene tetracosylidene group, etc. named. R 3 is thirdly a docosylidene group and, as such a fatty acid comprising R 3, is doxenoic acid named, When R 4 is an alkyl group Jr the same substances as R 3 are named, R 4 is preferably an octadecyl group and, as an amine comprising R 4, is octadecylamine named, when R 4 is a alkenyl group Jr the same substances as R3 nanedivane as well. R 4 is preferably an octadecylidene group and, like an amine comprising 84, octadecertylamine is named.
Examples of a preferred fatty acid amide represented by the expression (2) are hexadecanamide, (N-octadecenyl) hexadecanamide, and (N-octadecyl) dacosenamide.
An organic lubricant and an organic binder selected in the manner described above are mixed with a given organic solvate together with an iron powder to form an iron powder slurry. In the iron powder sizing, both the organic lubricant and the organic binder dissolve the organic solvent. The organic lasing agent from the jam powder is gradually phased out. Because Ora so precipitates the organic lubricant which has a lower solubility first on the surface of the jar powder and then the organic binder precipitates. The ratio of the solubility has the organic binder to which the organic lubricant (the latter) at a given temperature in a given solvent is dangerously 5 or higher and preferably 8 or higher (preferably 10 or higher). The upper limit for the ratio of solubility is not specifically limited, but is 20 or lower for external play.
When an iron powder slurry is prepared, the order for mixing an organic lubricant, an organic binder, an iron powder, and an organic solvent is not specifically limited and, for example, it is possible to: charge and stir an iron powder in a mixer; and, while stirring, adding an organic sealant, adding an organic lubricant and an organic binder, to the iron powder maleist instillation or atomization.
A method for producing an organic solvent is not specifically limited, a method for flattening a dried gas or a method for heating an iron powder slurry is named, and a method for heating an iron powder slurry is preferred. The pressure in this case is not specifically limited either, the atmospheric pressure or a reduced pressure can be assumed, and a preferred pressure is a reduced pressure of 650 mmHg or less in the degree of vacuum. For example, when an organic solvent is evaporated, an iron powder slurry can be heated to 40 DEG C. to 80 DEG C., and the quantity of the organic solvent after drying is preferably more than 0.1% of the quantity of the organic solvent before it is dried.
II If an organic lubricant and an organic binder are to be precipitated in this order, it is preferable to further adjust the quantities of those to be added. Specifically, when the ratio of the solubility of an organic binder to the solubility of an organic lubricant (the latter later) is considered as a, the quantity of the organic binder is preferably less Jn 100 xa, preferably no more Jn 75 xa, and even more preferably no more than 5n. 50 xa, per 100 parts by weight of the organic lubricant. For example, when the ratio of the solubility of an organic compound is the solubility of an organic lubricant (the latter later) is 8 or higher at a given temperature of a given solvent, the quantity of the organic barrier may be 400 to 400 parts by weight, 65 to 225 parts by weight, and preferably 80 to 130 parts by weight, per 100 parts by weight of the organic lubricant.
Furthermore, the total quantity of an organic lubricant and an organic binder: is determined according to the quantity of graphite and the quantity of other powders which will be described later; and is preferably from 0.3 to 2.0 parts by weight per 100 parts by weight of an iron powder. If the total quantity of an organic lubricant and an organic binder component is less than 0.3 parts by weight, the effect of improving flowability is shown to be insufficient and, on the other hand, it exceeds 2.0 parts by weight. The compressibility (density of shaped body) is adversely affected.
When an iron powder is charged with an organic lubricant and an organic binder as stated above, the powder can be charged electrostatically by friction between the powder particles or the like. The static electricity is neutralized within a period of time but, since the static electricity affects flowability, it is preferred that the powder not be electrostatically charged. The procedures for preventing electrostatic charge are a method of installing a neutralizing equipment such as an ionizer and a method of adding a surfactant or a high molecular weight antistatic agent, and in particular a process for adding a high molecular weight antistatic agent is preferably adopted. By using a high molecular weight antistatic component, it is possible to suppress the electrification of a powder and prevent the fluidity from deteriorating. As a high molecular weight antistatic agent, for example, such a styrene synthetic rubber or hydride thereof as described in Japanese Patent No. 289461 may be used. The weight average molecular weight thereof is, for example, not less than 10,000 and preferably 50,000 to 200,000. The quantity of an added antistatic agent is between 0.01 to 3 parts by weight and three times 0.03 to 1 parts by weight per 100 12 parts by weight of an iron powder for example. . If the quantity of an added antistatic agent is less than 0.01 parts by weight, the effect of preventing electrification is insufficiently achieved and, if it exceeds 3 parts by weight, the compressibility (density of shaped body) bond can be adversely affected.
A blanciat powder for powder metallurgy may contain a carbonaceous sasorn graphite, an alloy powder, etc. yid need. As an alloy powder, for example, a powder containing at least one type selected from the group consisting of copper, nickel, chromium, molybdenum, phosphorus and sulfur is named. Specific examples are a copper powder, a nickel powder, a chromium powder, a molybdenum powder, a phosphorus-containing alloy powder, a sulfur-containing powder, etc.
The content of a carbon cold is, for example, 0.5 to / 3 parts by weight per 100 parts by weight of a yam powder.
An alloy powder can be used either alone or in combination of tv5 or several varieties and the content is, for example, 1 to 5 parts by weight, more preferably 1.5 to 3 parts by weight, per 100 parts by weight of an iron powder.
In the manufacturing process of the present invention, when graphite, an antistatic agent, and an alloy powder are further added, for example, a method is used that, when an iron powder slurry is prepared, loading these materials into a mixer combined with an iron powder, stirring them, and adding an organic solvent. an organic smarjmeciel and an organic binciernedel are losta, to them.
For example, an iron powder used in the present invention may be either a pure iron powder or an iron alloy powder. The yarn alloy powder may be either a partially alloyed powder formed by dispersively adhering an alloying powder (for example, copper, nickel, chromium, molybdenum, or the like) to the surface of an iron-based powder or a color-alloyed powder obtained from a narrow yarn (or narrow steel) containing an alloying grain. . Dot iron-based powder is usually prepared by atomizing narrow jam or narrow steel. In this case, a jar-based powder may also be a reduced iron powder prepared by the iron ore or greased powder, a mixed powder for powder metallurgy obtained by a manufacturing process according to the present invention, an organic lubricant and an organic binder precipitate on the surface of a However, the mixed powder has an excellent lubricating ability, but, for the purpose of further enhancing the shape of the powder, it is possible to further use a powdered acid metal solvent (for example zinc stearate), wax (for example ethylenebisamide), or polyhydric hydroxide (e.g. ) combination. Such a powdered lubricant may be added after an organic lasing agent has been removed from an iron powder slurry. A mixed powder according to the present invention: may be used as a sintered part for machine structural use and the like, in particular faredradesvls to a part having a complicated thin-walled shape; has a good sintered body density, and can darrned reduce weight and improve hAllfssthet.
EXAMPLES The present invention is explained in more detail below with reference to the example.
The present invention is not limited by the following examples, it is superfluous to say that the present invention may be suitably modified within a range consistent with anteroposterior content and the modifications are all included within the scope of the present invention. Example 1 Organic Smoothing Agents and Organic Inhibitors which differ from each other twice or more at a given temperature, the use of toluene as an organic lasing agent is investigated. As a result, it has been found that when hexacecanoic acid amide is selected as an organic lubricant and stearic acid diester of ethylene glycol is selected as an organic binder, the solubility of the stearic acid diester of the ethylene glycol is about 10 times the solubility of the stearic acid diester of ethylene glycol a temperature range of about 60 ° C. Fig. 1 is a graph showing the solubilities of hexadecaric acid amide and stearic acid ester of ethylene glycol & toluene having a temperature range of 10 ° C to 60 ° C. Hg. 1, "fatty acid ester" represents stearic acid diester of ethylene glycol and "fatty acid amide" represents hexadecanoic acid amino.
Iron powder (Atmel 300M produced by Kobe Steel, Ltd., grain size: 180 pm or less) „copper powder (CE45 produced by Fukuda Metal Foil & Powder Co., Ltd.), 0th graphite powder (JCPB manufactured by Nippon Graphite lnolustries, Ltd.) sstsas i a mixer with bath and dryer power at a high speed for four minutes while a toluene solvent 14 which two (Experiment No. 1) ever tie (Experiment Nos. 2 and 3) types of organic compounds are dissolved, dropped or sprayed. The stirrer is successively switched to a mild layer and kept for about 10 minutes under a reduced pressure while hot water of 60 ° C is circulated through the jacket of the mixer and thus the welding agent is dried and deposited. Fig. 2 shows the mixing process. The two types of organic compounds are hexadecanoic acid amide (PNT manufactured by Nippon Fine Chemical Co., Ltd.) and stearic acid diester of ethylene glycol (EGDS produced by Nippon Fine Chemical Co., Ltd.) and a case of three types of organic compounds anyands, contains the two types of organic compounds, a styrene-butadiene copolymer (TR 2001C produced by aviSR Co., Ltd., molecular weight: 100,000) comprising parts by weight of styrene and 65 parts by weight of butadiene as an antistatic agent. The quantities of the added copper powder and graphite powder are 2 and 0, respectively. , 8 parts by weight, per 100 parts by weight of iron powder.
For example, an example of using only styrene-butadiene copolymer (Experiment No. 4) and an example of using only stearic acid diester of ethylene glycol (Experiment No. 5) as the organic compound to be dissolved in the toluene solution were also provided. the quantity of each material added per 100 parts by weight of the iron powder is shown in Table 1.
In varying from Experiments Nos. 1 to 5, after the organic lasing agent has been dried, a lubricant is added to a powder list described in Table 1 and mixed (mixed with stirring at a high speed for two minutes the mixer with biad), thus preparing a sample material for feeding powder properties. and the properties are measured by the following methods. Has, since fatty acid ester and fatty acid amide Sr load toluene and mixed a temperature range ay 10 ° C to 60 ° C, the solubilities a temperature range of 10 ° C to 60 ° C arneria TO be touched.
[Table 1] Experiment No. Organic icing agent Experiment No. 1 0.2 parts by weight of stearic acid diester of ethylene glycol Organic lubricant Substitute 0.2 parts by weight of hexadecanoic acid amide Experiment No. 2 0.2 parts by weight of stearic acid diester of ethylene glycol 0.2 parts by weight of stearic acid ester of ethylene glycol 0.2 parts by weight of hexadecanoic acid amide 0.2 parts by weight of hexadecanoic acid amide 0.05 parts by weight of styrene-butadiene sari / polymer 0105 parts by weight of styrene-butadiene copolymers Experiment No. 4 0.1 parts by weight of styrene-butadiene copolymers Experiment no. of stearic acid diester of ethylene bicarbonate * The quantity of each of the labeled materials is represented by proportion per 100 mass Organic solvent Lubricating powder 2 parts by weight of toluene 0.4 parts by weight of ethylene bisaride 2 parts by weight of tallier / 0.4 parts by weight of ethylene bisaride 2 parts by weight of toluene 0.4 parts by weight of polyhydroxycarboxylic acid amide 2 parts by weight of token 0.8 parts by weight of ethylene bis-arnide 2 parts by weight of tallie r / 0.8 parts by weight of ethylene-bis-amide parts of iron powders, 16 Mating of the graphite spreading fraction As shown in Fig. 3, a Nuclepore filter 1 (mesh size: 12 μm) where a glass tube 2 is placed (inner diameters: 16 mm, height: 106 mm) in which the lower part has a funnel shape, 25 g of a powder sample P is charged into it, N 2 gas is extracted from the bottom of the glass tube 2 at a rate of 0.8 liters per minute for 20 minutes, and a graphite spreading rate obtained from the following expression (3).
Graphite dispersion yield (%) = (1 - carbon quantity after N2 gas surface carbon quantity before N2 gas flow) x 100 (3) Feed density feed The bulk density (gicrri3) is given a powder spray in accordance with JS Z2504 (bulk density test method) for metal pipes.
Feeding of flowability The flowability (sec./50 g) ay a mixed powder dr matt in accordance with JS Z2502 (flowability test method for metal poly). Diet vili saga, a td (sec.) Sorn elapsed until 50 g of a mixed powder flattens out through an application of 2.63 mm J mats and the time (sec.) Is defined as the flowability of the mixed powder. a cylindrical container 114 mm inner diameters and 150 mm height with an outlet with a variable discharge diameter yid the batten is filled with 2 kg ay a powder proyi the condition that the outlet is closed, and kept for 10 minutes, Gradually, the outlet is opened gradually, the smallest diameter SOITI can empty the puiverproy mats, and the smallest diameter is defined as a critical discharge diameter.
A lower flowability (sec.) And a less critical emptying diameter mean a more unobtrusive flowability Feeding of density of a shaped body A columnar shaped body of 25 mm and a height of 15 mm there formed by granulating a powder spray at ordinary temperature (25 '). C) under a pressure of 490.3 MPa (Ticrn2) and a shaped crude density (gicrn3) is fed according to JSPM (Japan Society of Powder and Powder Metallurgy) Standard 1-64 (compression test method for metal powder). 17 (5) Dispensing Pressure Dispensing A dispensing pressure (MP) is obtained by dividing a load required to extract a molded body obtained by a molded body's derisity from a mold having a contact surface between the mold and the molded body. A smaller discharge pressure meant a slightly larger lubrication.
The results are shown in Table 2. [Table 2] Experiment no. Graphite dispersion percentage (Filliness (g / cm3) Flowability (sec.) Critical discharge diameter (mm) Shape of body density (g / cm3) Discharge pressure (MPa) 1 0 3.25 , 2 12,6,98 8.8 2 1 3.23 24.8 12.6,988.9 3 0 3.33 24.1 10,0 6.997.9 4 0 3,12 29.8 30.0 6.9710,2 3.31.3 25,0I6.9710.8 Ivan and one of the experimenter no. 1 to 3 years, the latter both an organic binder and an organic lubricant are used, the flowability and the critical depletion diameter Uteri and the extraction pressure are also small comparison lined experiments no. 4 and 5, in which single organic binders are used, but no organic lubricants are used. it has been found that the solubility and smorlOrmaga are superior to each of experiments no. 1 to 1 Example 2 The organic smarimole and the organic binders are mixed as shown in Table 3 and the properties of the powder samples are mated in the same way as Example 1. The results are shown in Table 4, 18 Organic binder Organic lubricant Antistatic agent & Organic welding agent 2 parts by weight of token 2 parts by weight of token 2 parts by weight of Winer / parts by weight of tartaric acid tartaric acid ester parts by weight of: -: tartaric acid diester of vene glycol 3 parts by weight of tartaric acid diester of vienglycol 04 parts by weight of 0.05 parts by weight of hexadecanoic acid amide styrene-butacylene copolymer 0.3 parts by weight of 0.05 pt butadiene copolymer species and one of the thawed materials is represented by a percentage per 100 parts by weight of the iron powder. Lubricating powder 0.4 parts by weight of ethylene bisamide 0.4 parts by weight of polyhydroxycarboxylic acid amide 0.4 parts by weight of polyhydroxycarboxylic acid amide 19 [T ] Experiment no. Graphite dispersion percentage (%) Bulky density (gicm3) Flowability (sec.) Critical discharge diameter (mm) Cast body density (gicm3) Discharge pressure (NIPa) 6 1 3.23 24.8 12.6.98 8, 9 7 3.26.1 15.0 6.98 6.8 8 0 3.22 23.2 10.0 6.98 9.6 It appears from Table 4 that good flowability and lubricity are shown in each of the experiments no. 6 tiii 8 and, in particular, the smarjfarmagan is good (that is to say uttaatstst the jerk is dense) when the quantity of fatty acid amide is greater than the quantity of fatty acid ester (Experiment No. 7) and usually the flowability is good (i.e. both the flowability and the critical excretion diurnal are small) when the quantity of fatty acid ester is greater than the quantity of fatty acid amide (Experiment No. 8). Accordingly, it is preferred that the quantities of both the blended materials be appropriately adjusted according to the properties required, and, in order to obtain both the effects of an organic binder and an organic lubricant at the same time, it is preferred that the quantities of the blaricated materials be is almost the same.
Explanation of references 1 Nuciepore filter 2 Glass tubes

权利要求:
Claims (10)
[1]
A process for preparing a mixed powder for powder metallurgy comprising the steps of: selecting an organic binder which, when the release of an organic lubricant at a given temperature a given organic solvent is said to be 1, has a solubility of 2 or more. given temperature the given discharge medium; mixing the organic lubricant and the organic binder with the given organic release medium together with an iron powder to produce an iron powder suspension in which the organic lubricant and the organic binder dissolve the organic release medium; and separating the organic release medium from the jar powder suspension by evaporation causes the organic lubricant and the organic binder to precipitate in this order.
[2]
The manufacturing process according to claim 1, wherein the ratio of the solubility of the organic binder to the insolubility of the organic lubricant (the latter) is represented by a, r the quantity of the organic binder is less than 100 x a per 100 parts by weight of the organic lubricant.
[3]
The manufacturing process according to claim 1, wherein the organic lubricant and the organic binder are mixed so that they amount in total to 0.3 to 2.0 parts by weight per 100 parts by weight of an iron powder.
[4]
The production process according to claim 1, wherein the organic solvent is an organic solvent of the aromatic hydrocarbons; the organic binder is a fatty acid ester represented by the following expression (1); and the organic lubricant is a fatty acid amide represented by the following expressions (2), RiC00-012-0-12-000R2 (1) (2) the terms represent and R2 aliphatic piston groups are identical riled ever different from each other, R3 represents an aliphatic piston group and R 4 represents a hydrogen atom or a piston group).
[5]
The manufacturing method according to claim 1, wherein the iron powder solution further comprises a hay molecule-like antistatic agent,
[6]
The manufacturing process according to claim 1, wherein part of the high molecular weight antistatic molecule Jr: a copolymer of styrene and synthetic yarn containing 5 to 95 parts by weight of styrene and 95 parts by weight of butadiene or isoprene as monomer components; or a hybrid of these.
[7]
The manufacturing process according to claim 1, wherein the organic lubricant is hexadecanoic acid amide, (N-octaclekenyl) hexadecanoic acid amiclver (N-octadecyl) docosenoic acid amide,
[8]
A mixed powder for powder metallurgy SOITI is obtained by the manufacturing process according to any one of claims 1 to 7.
[9]
9. A mixed powder for powder metallurgy, wherein an iron powder is coated with an organic lubricant and an organic binder,
[10]
The mixed powder undergoes powder metallurgy according to claim 9, wherein the proportion of the organic lubricant is more rigid on the inside than on the ointment of the coating layer below which the said iron powder is coated, 1/2 FIG. TOLUENE TEMPERATURE (C 100 1000
1. FATTY AC D ESTER
2. FATTY AC D AMI DE 0,1
0. 2-C) 4 0 Fl GF, 1 r ORGANIC ORGANIC ORGANIC 1- LUBRICANT, 1 11 POWDERED BINDER, LUBRICANT SOLVENT1 LI RON POWDER, 1 GRAPHI TE POWDER, ALLOYI NG POWDER DRYING 60 70 C) AMPLE POWDER OR MEOWUREMENT X ) 2/2 Fl G3

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同族专利:

公开号 | 公开日

US20130210687A1|2013-08-15|

KR20130100341A|2013-09-10|

CN103221163B|2015-05-06|

SE538244C2|2016-04-12|

JP2012111987A|2012-06-14|

WO2012070415A1|2012-05-31|

CN103221163A|2013-07-24|

KR101521369B1|2015-05-18|

JP5552032B2|2014-07-16|

US9149869B2|2015-10-06|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

JP2010260127A|JP5552032B2|2010-11-22|2010-11-22|Mixed powder for powder metallurgy and method for producing the same|

PCT/JP2011/076168|WO2012070415A1|2010-11-22|2011-11-14|Mixed powder for powder metallurgy and process for producing same|

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