JPH04116104A - Production of molded body for sintering and sintered parts - Google Patents

Abstract

PURPOSE:To shorten the time required to dewax a molded body consisting of metal powder, a binder and a sublimable substance without damaging the molded body by removing the sublimable substance by sublimation before dewaxing. CONSTITUTION:A molded body is formed with metal powder, a binder and 3-15wt.% sublimable substance which is solid at ordinary temp. This molded body is vacuum-treated under <=50 Torr pressure to sublime the sublimable substance and the resulting porous molded body is dewaxed and sintered. Even when the molded body is rapidly heated, the binder can flow out through the pores and the molded body is not damaged by cracking or swelling. Camphor, naphthalene or dichloro-benzene may be used as the sublimable substance.

Description

Detailed Description of the Invention [Industrial Application Field] The present invention is directed to molding metal powder by an injection molding method, an extrusion molding method, etc., and heating and sintering the obtained molded body for sintering to produce a sintered article. The present invention relates to powder metallurgy techniques for obtaining powder metallurgy, and in particular to methods for producing formed bodies and sintered articles.

[Conventional technology]

Conventionally, press molding, extrusion molding, and injection molding are known as methods for sintering powder to obtain various shapes.

Among these methods, injection molding can easily mold three-dimensional complex shapes, and in recent years, small-weight products that were traditionally produced by precision casting or machining can be mass-produced at low cost. Both metal powder and ceramic powder are being developed. Under these circumstances, in molding methods that require a process to remove the binder, a so-called debinding process, the debinding process can prevent breakage of the molded body due to expansion of the binder or maintain the shape of the molded body up to the sintering temperature. A wide variety of binders are used in combination for various purposes.

Binders suitable for this purpose are:
Diethyl tucrate (hereinafter referred to as DEP), which loses weight by 90% or more by 200°C, dibutyl phthalate, paraffin wax (hereinafter referred to as PW), which loses weight by 90% or more by 250°C, stearic acid, 30
Polybutyl methacrylate, polystyrene (hereinafter referred to as PS), which loses weight by 90% or more by 0°C, 3
Ethylene-vinyl acetate copolymer (hereinafter referred to as EVA), polyethylene, etc., which lose weight by 90% or more by 50°C, are known.

[Problem B to be Solved by the Invention] In the degreasing step, as described above, it is necessary to prevent damage to the molded body due to expansion of the binder or to maintain the shape of the molded body up to the sintering temperature. Therefore, in order to avoid damage to the molded body due to rapid expansion, evaporation, and decomposition of the binder, it is usually 50°C/Hr or less, preferably 10°C/Hr.
Heating is carried out at an extremely slow temperature increase rate of r or less.

For example, in the case of a temperature increase rate of 10° (:/llr), if the degreasing temperature is 500°C, it takes 50 hours to reach the degreasing temperature, which poses a problem of extremely low productivity.

In addition, Japanese Patent Application Laid-Open No. 2-438443 discloses mixing a sublimable substance such as camphor to promote degreasing, but in this case, degreasing is completed quickly, but the molded body is not damaged due to expansion of the binder. This is unavoidable and the rate of heating cannot be increased.

An object of the present invention is to provide a molded body for sintering and a method for producing a sintered article that can shorten the degreasing time without causing damage to the molded body even if the degreasing speed is increased.

[Means to solve the problem]

The present invention is a molded body for sintering that contains metal powder, a binder, and 3-15% by weight of a sublimable substance that is solid at room temperature.

By containing 3 to 15% by weight of the sublimable substance, the molded article can be made porous by the volume of the sublimable substance by removing the sublimable substance before degreasing. The greatest feature of the present invention is that the range of the sublimable substance is specified so as to form such a porous body.

Thanks to these pores, even when heated rapidly, there is enough volume for the binder to flow out, so no abnormalities such as cracking or blistering are observed in the molded product. If the content of this sublimable substance is less than 3% by weight, even if vacuum treatment is performed at room temperature, the volume will be too small and no substantial effect will be obtained; if it exceeds 15% by weight, the volume of the pores will decrease. If it is too large, the dimensional accuracy of the fired crystal will drop significantly, so it was limited to this range.

As the sublimable substance, any substance with high sublimability such as camphor, naphthalene, dichlorobenzene, adamantane, trimethylenenorbornane, etc. may be used.

In addition, the present invention produces a molded product containing 3 to 15% by weight of a sublimable substance in addition to a molding binder in metal powder, in a 50 t
This method of manufacturing a sintered part is characterized in that the sublimable substance is sublimated by vacuum treatment at a pressure lower than orr, followed by degreasing treatment, and then sintering.

The sublimable substance is used to make the molded body porous.
In order to prevent the binder from expanding, it is necessary to sublimate it before heating it for degreasing. For this purpose, vacuum treatment can be used to reduce the pressure to 5 Q torr or less.

This makes it possible to perform degreasing without damaging the molded product even at a temperature increase rate of 70° (:/Hr or more).

In addition, when the molded body is immersed in an organic solvent such as methylene chloride or acetone after vacuum treatment, sublimable substances sublimate and the molded body becomes porous, so the organic solvent penetrates into the inside of the molded body and removes the binder. A portion of it is eluted in a short period of time, and porosity is promoted, so the temperature increase rate can be further increased.

[Example] An example of the present invention will be described. Note that the present invention is not limited to the following examples.

(Example 1) The raw material powder was 5US304L water atomized powder with an average particle size of 7.4 μm, and the binders were 2.3 parts by weight of actic polypropylene (hereinafter referred to as parts by weight unless otherwise specified), 5 parts of EVAl, P SO, 7 parts, P W 1.
2 parts, 1.0 part of DEP, and 10.0 parts of dichlorobenzene as a sublimable substance were kneaded using a pressure kneader to form a compound. This compound was placed in a mold kept at 25°C, cylinder temperature: 95°C, injection pressure: 9. I
G P a, wall thickness 5[[1IIl, length 20In[[
It was injection molded into a shape with a width of 6 mm. This injection molded product was subjected to vacuum treatment in which it was held in a vacuum furnace at 3 Q torr for 1 hour, and it was confirmed that the amount of dichlorobenzene, which is a sublimable substance, was reduced. The molded body whose weight loss was confirmed was degreased at 600°C in a hydrogen atmosphere at an average heating rate of 10°C/Hr. Thereafter, sintering was performed in a vacuum furnace at 1250°C and 11O-4 torr to obtain the desired sintered body. The obtained sintered body had a relative density of 97%, and was in good condition with no defects such as cracks and blisters.

(Example 2) A molded body prepared in the same manner as in Example 1 was heated at an average heating rate of 70%.
Degreasing was performed at 600°C in the same manner as in Example 1, except that the temperature was changed to 600°C/Hr. Thereafter, sintering was performed in a vacuum furnace at 1250'C110-'torr to obtain the desired sintered body. The obtained sintered body had a relative density of 97%, and was in good condition with no defects such as cracks and blisters.

(Example 3) A molded article prepared in the same manner as in Example 1 was subjected to the same vacuum treatment as in Example 1. The obtained molded body was subjected to ultrasonic cleaning with an output of 45 KHz in methylene chloride for 10 minutes,
A 15% reduction in the amount of binder used was confirmed. The molded product whose weight loss was confirmed was heated to an average of 10°C/10°C in a hydrogen atmosphere.
Degreasing was carried out at 600°C at a heating rate of Ilr. Thereafter, sintering was performed in a vacuum furnace at 1250"C110-'torr to obtain the desired sintered body. The relative density of the obtained sintered body was 97%, and it was in good condition with no defects such as cracks and blisters. there were.

(Example 4) A molded body obtained in the same manner as in Example 3 was heated at an average heating rate of 20
Degreasing was carried out at 600°C in the same manner as in Example 3, except that the temperature was changed to 0°C/Hr. Thereafter, sintering was performed in a vacuum furnace at 1250°C and 110 torr to obtain the desired sintered body. The obtained sintered body had a relative density of 97%, and was in good condition with no defects such as cracks and blisters.

〔Effect of the invention〕

According to the present invention, even if the temperature increase rate in the degreasing process necessary to obtain a sintered body is increased, no damage will occur to the molded body, so the time required for the degreasing process can be significantly shortened, and productivity can be increased. You can improve.

Claims (4)

[Claims] (1) A molded body for sintering containing metal powder, a binder, and 3-15% by weight of a sublimable substance that is solid at room temperature. (2) A molded article containing 3-15% by weight of a sublimable substance in addition to a molding binder in metal powder is subjected to vacuum treatment at a pressure lower than 50 torr to sublimate the sublimable substance, and then A method for manufacturing sintered parts, characterized by performing degreasing treatment and then sintering. (3) The method for producing a sintered part according to claim 2, characterized in that after sublimating the sublimable substance, immersing in an organic solvent and melting a part of the binder is followed by degreasing. . (4) The method for manufacturing a sintered article according to any one of claims 2 to 3, wherein the degreasing treatment includes a step of heating at an average temperature increase rate of 70° C./Hr or more.