JP5182648B2 - Method for producing porous aluminum sintered body - Google Patents

Description

The present invention relates to a method for producing a porous aluminum sintered body that can be used for, for example, components of fuel cells, capacitors, and secondary batteries.

  Recently, in the field of fuel cells, a gas diffusion layer or catalyst carrier that is disposed between the MEA (membrane / electrode assembly) and a flat metal separator to secure a fuel gas flow path, and a capacitor or 2 In the field of secondary batteries, aluminum porous bodies that are lightweight, have good conductivity and heat conductivity have attracted attention as electrode materials that need to be coated with a positive electrode or negative electrode active material to the inside.

  Conventionally, the main method for producing an aluminum porous body is a casting method. That is, it is well known that a foaming agent such as titanium hydride is added to an aluminum melt and foamed, and this is produced by a method of forming pores between aluminum skeletons. Since this is lightweight and has a capability of absorbing impact energy and sound absorption, it has been put to practical use as a shock absorber for automobile bodies and a building material for sound absorption. However, since the porous body manufactured by this method is independent of each pore and is not in communication (closed pore), it can be used for applications requiring fluid permeation, electrodes for capacitors, secondary batteries, etc. Cannot be used for

  Therefore, as a method for producing an open-pore aluminum porous body in which pores communicate with each other, polyurethane foam is embedded in a refractory material, and this is baked to remove the polyurethane to make a mold, and then aluminum is formed there. An “investment casting method” in which a porous body having a three-dimensional network structure having the same structure as that of polyurethane foam is obtained by pressure casting the molten metal has been proposed, and a porous body having excellent fluid permeability can be obtained. (Patent Document 1). However, the porous body by the method of Patent Document 1 is advantageous in terms of fluid permeability, but has a small skeleton and a smooth surface, so that the surface area is small, and the casting method is the base. Therefore, it is not suitable for producing a fine pore porous material.

  For this reason, for example, a powder metallurgical process proposed by the present applicant is effective for producing a porous aluminum sintered body having a large skeleton surface area (Patent Document 2). That is, this is a technique in which raw material powder and a binder are mixed and kneaded to form a molded body, followed by heat degreasing and then sintering. And if necessary, in order to form pores, that is, according to the assumed size of the pores, particles of a size that takes into account the shrinkage rate of the compact during the sintering are mixed and kneaded. In this method, a molded body in which the particles are dispersed is extracted, and the particles are extracted with a solvent, followed by heat degreasing and sintering. According to this method, in addition to the pores, the amount of pores formed in the skeleton and the diameter are large, so the degree of freedom in design is large. A sintered material can be provided.

JP 54-083624 A JP 2004-3000526 A

  The method of Patent Document 2 is effective in achieving a porous sintered body having a large skeleton surface area. However, when the sintered body is made of aluminum, there are problems peculiar to it. That is, before sintering, the surfaces of the aluminum raw material powder constituting the molded body are required to be clean from each other. Since aluminum is active, the powder surface is easily covered with an oxide film. . If the powder surface is covered with an oxide film, formation of necks (bonding portions) between the raw material powders is hindered, and sintering does not proceed sufficiently.

An object of the present invention is limited to aluminum porous sintered body, a neck at the sintering process is to provide a method for producing a fully-formed porous sintered aluminum.

  The present inventor first examined effective removal means for the oxide film on the surface of the raw material powder, which is one factor that hinders the formation of the neck. In addition to this, it was determined that it was a binder residue (carbon) present around the contact portion between the raw material powders as a factor inhibiting the growth of the neck, and an effective reduction means was also examined. As a result, the above-described means for removing or reducing the aluminum raw material powder in the sintering process that can expose the metal surface has been found, and the present invention has been achieved.

That is, in the present invention , an aluminum powder and polyvinyl alcohol are mixed and kneaded so that the proportion of polyvinyl alcohol is 3% by mass or less when the total mass of the aluminum powder and polyvinyl alcohol is 100% . Thereafter, the method is a method for producing a porous aluminum sintered body characterized by heating and degreasing and then sintering in a vacuum or an inert gas atmosphere in a furnace provided with magnesium and / or calcium. Preferably, as one form, a method for producing a porous aluminum sintered body having a skeleton obtained by sintering aluminum powder around pores, in which aluminum powder, polyvinyl alcohol, and particles for forming the pores are mixed This is a method for producing a porous aluminum sintered body which is kneaded to form a molded body in which the particles are dispersed, the particles are extracted with a solvent, and then heated and degreased. The particles are preferably made of wax. And as sintering conditions, Preferably, it carries out at the temperature of 590-635 degreeC.

  According to the present invention, it is possible to provide a porous aluminum sintered body having a large surface area or having a high degree of freedom in designing the amount and diameter of pores and pores.

It is a scanning electron micrograph which shows an example of the neck part of the porous aluminum sintered compact of this invention. It is a scanning electron micrograph which shows an example of the neck part of the porous aluminum sintered compact of this invention. It is a scanning electron micrograph which shows an example of the neck part of the porous aluminum sintered compact of a comparative example. It is a scanning electron micrograph which shows an example of the neck part of the porous aluminum sintered compact of a comparative example. It is a schematic diagram which shows the preparation form of sintering performed in the Example.

As described above, an important feature of the present invention is that, in addition to the oxide film on the surface of the raw material powder being one factor that hinders the formation of the neck, it is present around the contact portion between the raw material powders. The fact that it is a binder residue (carbon) is also found. And the effective removal and reduction means of an oxide film and a binder residue in order to eliminate these factors have just been specified. Hereinafter, the constituent requirements of the preferred porous aluminum sintered body produced by the present invention will be described.

-Carbon is regulated to 0.05% or less by mass%.
For example, in the manufacturing process of Patent Document 2, most of the organic binder in the molded body decomposes and dissipates in the heating process of degreasing and sintering, but if there is a large amount of binder residue, it is the contact portion between the powders. In order to remain surrounding the periphery, the growth of the neck is inhibited. And since a residue has carbon as a main component, the residual amount can be evaluated exclusively as the carbon amount of the sintered body after sintering. Thus, as a result of an experimental investigation on the amount of carbon in the sintered body that can achieve sufficient neck formation, it has been found that it is effective to regulate it to 0.05% or less. Desirably, it is 0.04% or less.

-Restrict oxygen to 0.3% or less by mass%.
Regarding the dense oxide film formed on the powder surface, which is another sintering inhibiting factor, it is necessary to suppress the growth only in the heating process of degreasing and sintering. Therefore, the oxide film, during sintering, and be removed by the use of getter chromatography described later, whereby it is possible to promote diffusion of aluminum atoms at the contact portion of the powder particles. And the grade of an oxide film can be evaluated exclusively as the amount of oxygen in the sintered body after sintering. Therefore, as a result of an experimental investigation on the amount of oxygen in the sintered body, it was found that the amount of oxygen in the sintered body obtained under sufficiently advanced sintering conditions was 0.3% or less. Desirably, it is 0.25% or less, and further 0.2% or less. Even if the amount of oxygen is higher than 0.3%, it may be possible to promote the sintering by raising the sintering temperature. It is difficult to obtain a sintered body. Sintering itself does not proceed sufficiently for the oxygen content of 0.4%.

-It has a framework in which aluminum powder is sintered around the pores.
Moreover, as a structure of the porous body of this invention, it is preferable to have the frame | skeleton which aluminum powder sintered around the void | hole as patent document 2, for example. That is, when a porous sintered body is manufactured by directly sintering coarse powder to introduce pores, it is closer to the shape of the pores formed in the skeleton rather than the pores of the present invention. . The porosity is determined exclusively by the tap density and sintering conditions of the raw aluminum powder and is at most about 50% by volume. However, for example, by the manufacturing method of the present invention using particles for forming pores described later, by taking a structure having a skeleton obtained by sintering aluminum powder around the pores, about 70% by volume, or A porous body having a high porosity of, for example, 90% by volume or more is obtained. Typically, a porous body having a porosity of 70 to 95% by volume is obtained. This is advantageous for applications such as a catalyst carrier and a gas diffusion layer of a fuel cell that allow fluid to permeate at a low pressure loss, and for a capacitor and an electrode material of a secondary battery.

Next, as a method for producing the porous aluminum sintered body of the present invention, aluminum powder and polyvinyl alcohol are mixed and kneaded to form a molded body, then heated and degreased, and then placed in a furnace provided with magnesium and / or calcium. This is a method of sintering.

  First, when the above heat degreasing is a step of removing the binder in the molded body, since the aluminum powder has a low melting point and easily oxidizes, the degreasing temperature is set lower than that of the iron-based material. There is a need. Accordingly, since about 95% of polyvinyl alcohol is decomposed even at a low temperature of 500 ° C. in an argon gas atmosphere, it is effective to use polyvinyl alcohol as a binder for forming aluminum powder in order to reduce binder residue.

  In addition to the above, within a range in which the shape of the molded body can be maintained, it is also a preferable means for suppressing the binder residue to keep the amount of polyvinyl alcohol mixed with the aluminum powder low. Specifically, the proportion of polyvinyl alcohol is limited to 3% by mass or less, desirably 2% by mass or less, when the total mass of aluminum powder and polyvinyl alcohol is 100%. About a minimum, 0.2 mass% or more is desirable and 0.5 mass% or more is good. Polyvinyl alcohol may be mixed as an aqueous solution or an alcohol solution, for example. Depending on the shape of the molded body, a plasticizer or a gelling agent may be further added to facilitate the molding itself.

  Further, at the time of sintering, magnesium or calcium having a lower oxide generation energy than aluminum (that is, preferentially oxidized more easily than aluminum) is attached to the furnace. As a result, the sublimated magnesium or calcium acts as a getter that removes a dense aluminum oxide film on the surface of the powder, so that sintering can be promoted. The above calcium can be used in the form of an alloy such as calcium silicon which is easy to handle.

  Furthermore, it is preferable that the kneaded body is also mixed with particles for forming pores to form a molded body in which the particles are dispersed. The particles are subjected to solvent extraction in a subsequent process to form pores in the final sintered body. That is, by adding the above-mentioned particles to the starting material, the position where the particles are located becomes a cavity corresponding to the size, and around the pores, which is a preferred form of the porous aluminum sintered body of the present invention. A skeletal structure in which aluminum powder is sintered is obtained. The particles capable of solvent extraction include, in a broad sense, room temperature solid organic compounds such as resins. Among these, those made of wax are easy to adjust in size and are soluble in various solvents, and therefore, for example, using an organic solvent makes it easy to handle and extract and remove.

Then, the sintering is performed in a vacuum or an inert gas atmosphere which is a non-oxidizing atmosphere . It is preferable to carry out at a temperature of 590-635 degreeC. When the getter of the present invention, particularly magnesium, is placed in a sintering furnace as a getter and vacuum sintering is performed, if the sintering temperature is lower than 590 ° C. and no longer than 580 ° C., in addition to the getter action, diffusion of aluminum atoms Since it itself is insufficient, the sintering strength is weakened. Further, when the sintering temperature is higher than 635 ° C., the aluminum raw material itself is melted to close the pores and pores or generate spherical droplets on the surface of the sintered body. This melting is thought to be due to the fact that the aluminum raw material reacts with getter, particularly magnesium vapor, to form a low melting point alloy. The sintering temperature is more preferably 600 to 630 ° C. About an upper limit, 625 degrees C or less, Furthermore, 620 degrees C or less is more preferable.

  The material of the porous aluminum sintered body of the present invention is not limited to pure aluminum. That is, for the purpose of compensating the strength and the like depending on the application, the effects of the present invention are exhibited even with conventionally known aluminum alloys and other aluminum alloys.

(Production of test piece)
Pure aluminum powder of 100 mesh or less, powder obtained by mixing paraffin wax particles having an average particle diameter of 180 μm with the pure aluminum powder at a volume ratio of 20:80, and volume of paraffin wax particles having an average particle diameter of 400 μm to the pure aluminum powder. Three kinds of raw material powders, powders mixed at a ratio of 15:85, were prepared. Each of these raw material powders was mixed with an aqueous polyvinyl alcohol solution as a binder, kneaded, stretched to a thickness of about 1 mm with a roller, naturally dried, and then cut into a sheet-like molded body of about 40 mm square. . The molded body mixed with the paraffin wax particles was further immersed in an organic solvent to remove the paraffin wax particles and then dried.

  Next, the obtained molded body was degreased at 500 ° C. in an argon gas at atmospheric pressure. As schematically shown in FIG. 5, the degreased body 1 is placed on a ceramic tray 2, a getter 3 made of magnesium ribbon or calcium silicon lump is installed at the end of the tray 2, and molybdenum A box-like lid 4 made of metal was covered. Then, the tray covered with the lid was put in a furnace and sintered at a temperature of 600 to 640 ° C. in a vacuum to prepare a test piece.

  Table 1 shows the production conditions of the test piece. The PVA mixing amount in the table is the mass% of the PVA when the total mass of the aluminum raw material powder and the polyvinyl alcohol (PVA) is 100%.

(Test piece survey results)
Table 2 shows the carbon content and oxygen content of the test pieces obtained under the conditions shown in Table 1 and the state of the sintered body. In the state of the sintered body, a 90 ° bend test was conducted as an evaluation of whether the neck formation during the sintering process was sufficiently advanced (whether sufficient sintering strength was achieved), and there was no breakage in appearance. Bent for bent (having ductility), △ (slightly lacking in ductility) for bending with slight breakage in appearance but not for bending, and x (ductility) for bending and could not bend None).

  In the example of the present invention, the test pieces 1, 3, 4, 5, 7, and 8 manufactured at a sintering temperature of 600 to 630 ° C. with a minimum amount of binder added and with a getter included are: The amount of carbon and the amount of oxygen are kept low, and the state of the sintered body is excellent. Even with the test piece 3 having a low sintering temperature, a porous aluminum sintered body having ductility was obtained although it was slightly weak in strength. FIG. 1 is a scanning electron microscope (SEM) photograph in which the neck portion of the test piece 1 is observed, and FIG. 2 is the same photograph in which the surface is further observed at a high magnification. In the test piece 1 having a low carbon content, no binder residue is observed around the neck, and the neck is sufficiently grown. Further, the test piece 1 having a low oxygen content has a wide exposed metal portion that looks black and smooth. In the case of the test piece 6 having a high sintering temperature of 640 ° C., a sintered body having ductility was obtained, but formation of spherical droplets was observed on the surface.

  On the other hand, in the comparative example, the test piece 2 produced by adding a large amount of binder has a high oxygen amount in addition to an increase in the carbon amount due to the binder residue, and in a state in which the sintering is hardly progressed. there were. The increase in the amount of oxygen is considered to be a result of increasing the amount of binder added because not only a small amount of binder but also oxygen is contained. FIG. 3 is an SEM photograph in which the neck portion of the test piece 2 is observed, and it can be seen that a film-like binder residue surrounds the contact portion between the powders and inhibits neck growth. FIG. 4 is the same photograph of the powder surface of the test piece 2 observed at a higher magnification. It can be seen that the surface is completely covered with alumina, and the black and smooth metal portion is not exposed.

  The test piece 9 manufactured without installing a getter at the time of sintering had a high oxygen content and could be handled because the oxide film on the surface of the aluminum powder was not sufficiently removed. It was a body. The same form is confirmed in the test piece 2 also about the neck part of the test piece 9 and the powder surface.

  1. Degreased body, 2. Tray, 3. Getter, 4. Lid

Claims (4)

Aluminum powder and polyvinyl alcohol were mixed and kneaded so that the proportion of polyvinyl alcohol was 3% by mass or less when the total mass of aluminum powder and polyvinyl alcohol was 100%, and then degreased by heating. Then, a method for producing a porous aluminum sintered body, comprising sintering in a vacuum or an inert gas atmosphere in a furnace provided with magnesium and / or calcium. A method for producing a porous aluminum sintered body having a skeleton obtained by sintering aluminum powder around pores, in which aluminum powder, polyvinyl alcohol, and particles for forming the pores are mixed and kneaded; 2. The method for producing a porous aluminum sintered body according to claim 1 , wherein the sintered body is formed by dispersing the particles with a solvent, followed by heat degreasing. The method for producing a porous aluminum sintered body according to claim 2 , wherein the particles for forming the pores are made of wax. Sintering is performed at the temperature of 590-635 degreeC, The manufacturing method of the porous aluminum sintered compact in any one of Claim 1 thru | or 3 characterized by the above-mentioned.