JP4139804B2 - Method for producing metal foam - Google Patents

Description

  The present invention relates to a method for producing a metal foam. In particular, the present invention relates to a method for producing a metal foam, in which a metal foam having improved heat insulation in the thickness direction can be obtained by introducing a large number of disk-like pores parallel to the plane direction of the metal foam.

  Foamed materials are lightweight and are applied in various fields as materials excellent in heat insulation and soundproofing. For example, in a container for transporting and storing hydrogen in a liquid hydrogen state (tank for liquid hydrogen), an aluminum alloy that is durable against low-temperature embrittlement and hydrogen embrittlement is used on the inside, and heat insulation is excellent on the outside. In general, a structure in which a polymer foam such as urethane is attached is adopted. In the case of a container having such a structure, since the aluminum alloy itself has no heat insulation property, if the container is filled with liquid hydrogen for a long time, the polymer foam of the container reaches the liquid hydrogen temperature (20K). As a result, as the air in the pores inside the foam is liquefied, the internal pressure of the pores is drastically decreased, and the polymer foam cannot be maintained in its structure and is crushed. In order to solve this problem, attempts have been made to improve the strength of the polymer foam and increase the thickness, but this involves new problems such as an increase in the manufacturing cost and size of the container. Therefore, the actual situation is that no effective solution has been obtained. On the other hand, if the aluminum alloy used inside the liquid hydrogen tank can have heat insulating properties, the above problem can be solved by suppressing the temperature drop of the polymer foam due to the liquid hydrogen filled in the tank. It is considered that the thickness of the polymer foam can be reduced and the weight and size of the container can be reduced.

As a method for producing a metal foam using various metals or alloys such as aluminum, conventionally, a method in which a metal powder and a foaming agent are mixed and bulked and then made porous by heating has been employed. For example, Japanese Patent Application Laid-Open No. 2001-342503 discloses a method in which a metal powder and a hydride powder are mixed and sealed in a container, and the powder is bulked by applying strong processing at an intermediate temperature, followed by high temperature superplasticity A method for producing a porous body is disclosed in which a hydride is decomposed under expression processing conditions to make a bulked material porous. Japanese Patent Laid-Open No. 2001-342504 discloses a method in which a metal powder and a hydride powder are mixed and sealed in a container, and the powder and the container material are integrated simultaneously with the bulking of the powder by applying strong processing at an intermediate temperature. A method for producing a composite porous body is disclosed, in which a hydride is decomposed under high-temperature superplasticity processing conditions to make a bulked material porous.
All of these methods use expensive metal powder as a raw material for production, and thus have a problem that the production cost of the foam increases. In addition, since the foam obtained has inevitably spherical pores from the manufacturing process, the foam can be reduced in weight by these conventional methods. It was difficult to get.

JP 2001-342503 A JP 2001-342504 A

  Therefore, the present invention can obtain a metal foam having a low thermal conductivity in the thickness direction and improved heat insulation compared to the conventional foam having spherical pores, And it aims at providing the manufacturing method of the metal foam whose manufacturing cost is cheap compared with the conventional method.

As a result of diligent research to solve the above-mentioned problems, the inventors of the present invention performed superplasticity of the preform obtained by joining a metal plate by rolling with a foaming agent between a plurality of metal plates made of a superplastic metal. Based on the knowledge that it is possible to obtain a metal foam having excellent heat insulation in the thickness direction by decomposing and foaming the foaming agent by heating at the superplastic temperature of the metal, and the present invention has been completed. It is a thing.
Although not bound by any theory, according to the method of the present invention, a rolled texture having anisotropy can be formed by rolling and joining metal plates sandwiching a foaming agent. In addition, the anisotropy of the rolling texture is maintained by decomposing and foaming the foaming agent by heating the preform at the superplastic temperature using a metal having superplasticity as the material constituting the metal plate. Since foaming can be performed as it is, anisotropy occurs in the foaming direction due to the decomposition of the foaming agent, and the shape of the pores in the resulting metal foam is a disk shape (the sphere is crushed in the thickness direction of the metal foam) Therefore, it is considered that a metal foam having a low thermal conductivity in the thickness direction and an improved heat insulating property can be obtained when compared at the same porosity as compared with a conventional foam having spherical pores. .

That is, the present invention provides a step of preparing a plurality of metal plates made of superplastic metal and a powdery foaming agent, and sandwiching the foaming agent between the plurality of metal plates, and the plurality of metals sandwiching the foaming agent. Rolling a plate and joining the plurality of metal plates to each other to obtain a preform; and heating the preform at a superplastic temperature of the superplastic metal to decompose and foam the foaming agent. The manufacturing method of a metal foam including a process is provided.
In the method of the present invention, the step of obtaining the preform further includes a step of cutting the plurality of metal plates joined together, and a step of superimposing the cut metal plates and rolling the superposed metal plates. It is preferable to include the process including 1 or more times.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to manufacture the metal foam improved in the heat insulation of the thickness direction at low cost.

In the method of the present invention, first, a plurality of metal plates made of superplastic metal and a powdery foaming agent are prepared, and the foaming agent is sandwiched between the plurality of metal plates.
The metal plate used in the present invention is not particularly limited as long as it is made of a superplastic metal and can be rolled. An Al-Mg-based (5000-based) alloy, an Al-Zn-Mg-based (7000-based) alloy, Aluminum alloys such as Al-Cu-Mg (2000) alloy, Al-Mg-Si (6000) alloy, magnesium alloys such as AZ31 and AZ91, titanium alloys such as Ti-6Al-4V and SP700, Zn- An alloy plate such as an Al eutectoid alloy or an iron alloy can be preferably used. Among these, it is preferable to use an aluminum alloy from the viewpoint of lightness and the like, and it is more preferable to use a 5083 aluminum alloy excellent in superplastic characteristics.
Note that the number of metal plates to be used can be determined as appropriate depending on the thickness of the metal plate, the performance of the rolling device used in the rolling process, the porosity of the metal foam to be obtained, and the like. When the overall thickness of the rolling object is increased, a high-performance rolling apparatus with a large rolling force is required. Therefore, the number of metal plates to be used is preferably about 2 to 12, and The thickness is desirably about 0.5 to 3 mm. The porosity of the metal foam to be obtained by the method of the present invention is usually about 30 to 80%.
On the other hand, the powdery foaming agent used in the present invention is not particularly limited as long as it can be sufficiently decomposed and foamed at the superplastic temperature of the superplastic metal used, such as titanium hydride, zirconium hydride, etc. Inorganic foaming agents, azo organic foaming agents such as azodicarbonamide (ADCA), or organic foaming agents such as hydrazine derivatives such as p, p'-oxybisbenzenesulfonylhydrazide (OBSH) can be suitably used. . In order to obtain a good metal foam, it is desirable to use a foaming agent having a decomposition temperature close to the superplastic temperature of the superplastic metal used. From such a viewpoint, it is preferable to use an inorganic foaming agent having a decomposition temperature generally higher than that of the organic foaming agent. For example, when the 5083 aluminum alloy having a superplastic temperature of 500 to 550 ° C. is used as the superplastic metal, it is preferable to use titanium hydride having a decomposition temperature of about 400 ° C.
In general, the particle size of the powdered foaming agent is desirably sufficiently small, but is preferably about 10 to 50 μm from the viewpoint of the problem of powder aggregation in the working process.
When sandwiching a powdered foaming agent between a plurality of metal plates, for example, spray the foaming agent while sieving on the surface of one metal plate, and then stack another metal plate on it. That's fine.
Further, the amount of the foaming agent used can be appropriately determined depending on the porosity of the metal foam to be obtained and the types of the foaming agent and superplastic metal to be used. For example, when the 5083 aluminum alloy is used as the superplastic metal and the titanium hydride foaming agent is used as the powdery foaming agent, the pores are prevented from easily coalescing and coarsening, while the preform From the standpoint of ensuring proper foaming, it is preferable to use a powdered titanium hydride blowing agent of about 0.5 to 1.5% by weight based on the weight of the 5083 aluminum alloy plate.

Next, in the method of the present invention, a plurality of metal plates sandwiching a foaming agent are rolled, and the plurality of metal plates are joined together to obtain a preform.
The metal plate may be rolled by a conventional method, for example, roll rolling such as cold roll rolling. Moreover, what is necessary is just to determine suitably the pressure applied to a metal plate in the case of rolling according to the kind etc. of the superplastic metal which comprises a metal plate. Similarly, the rolling speed can be appropriately determined depending on the performance of the rolling apparatus used. In addition, these conditions and other rolling conditions are required to obtain a preform in which a plurality of metal plates are bonded to each other by rolling, and to form a rolling texture having anisotropy, etc. Therefore, it is necessary that anisotropy is generated in the foaming direction when foaming is caused by decomposition of the foaming agent. Specifically, the rolling reduction during rolling is desirably 50% or more. However, the above-mentioned effect by rolling does not need to be achieved by one rolling, and the preform may be obtained by repeating the rolling a plurality of times to achieve the above-mentioned rolling effect.

In the method of the present invention, the step of obtaining the preform further includes a step of cutting a plurality of metal plates joined together, and a step of superimposing the cut metal plates and rolling the stacked metal plates. Is preferably contained once or more.
A specific aspect of this step will be described with reference to the drawings. First, in the first step, a plurality of metal plates 1 made of superplastic metal and a powdery foaming agent 2 are used in the first step. Prepare and spray the foaming agent 2 while sieving on the surface of one metal plate 1, and then stack another metal plate 1 on top of it and repeat these operations. The foaming agent 2 is sandwiched between the two. Next, in the second step, a plurality of metal plates 1 sandwiching the foaming agent 2 are rolled using a rolling mill 3, and when a plurality of metal plates are joined together to obtain a preform, they are joined together. The operation | work which cut | disconnects a some metal plate, piles up the cut | disconnected metal plate, and rolls the piled metal plate is performed once or more.
Here, the method of cutting the joined metal plates may be a conventional method. Further, the number of times of repeating the cycle consisting of cutting, superimposing and rolling can be appropriately determined depending on the porosity of the metal foam to be obtained. Generally, from the viewpoint of improving the dispersion state of the foaming agent in the metal plate, it is preferable to increase the number of repetitions. However, the number of repetitions is adjusted according to the thickness and number of metal plates at the start. It is desirable to do. For example, when the thickness of the starting metal plate is 1 mm and the number of sheets is 6 and the above rolling cycle is repeated n times with the rolling reduction during rolling being 50%, The number of interfaces is 5 × 2 ⁿ⁻¹ , and the average distance between the interfaces is 6 × (5 × 2 ⁿ⁻¹ ) ⁻¹ mm. That is, the average interval between the interfaces in this case is 37.5 μm when the number of repetitions of the cycle is 6, and 9.375 μm when the number of repetitions is 8, so when the particle size of the foaming agent is about 10 to 50 μm, This number of cycles is sufficient, and even if the number of cycles is increased further, it is considered that further improvement in the state of dispersion of the foaming agent cannot be expected.
When the cut metal plates are stacked, an additional foaming agent may be sandwiched between the stacked metal plates.

In the method of the present invention, the preform obtained in the above step is further heated at the superplastic temperature of the superplastic metal to decompose the foaming agent and foam, thereby obtaining a metal foam.
The temperature at which the preform is heated is the superplastic temperature of the superplastic metal constituting the metal plate, and may be determined according to the type of superplastic metal to be used. Usually, 0.7Tm ≦ T ≦ 0.85Tm (In the formula, Tm is the melting point at the absolute temperature of the superplastic metal to be used). Moreover, the said heating temperature needs to be the temperature more than the decomposition temperature of a foaming agent. In the present invention, it is important to cause anisotropy in the foaming direction due to the decomposition of the foaming agent by performing foaming while maintaining the anisotropy of the rolling texture obtained by rolling, From such a viewpoint, it is necessary to determine heating conditions such as the heating temperature and heating time of the preform. For example, if the preform is heated to near the melting point, the flow stress of the matrix is extremely reduced, so that it is extremely difficult to maintain the anisotropy of the rolling texture, but it is heated at the superplastic temperature as described above. In this case, such a problem does not occur.
The heating method for the preform can be the same regardless of the type of superplastic metal used, but when using a superplastic metal containing a material that easily oxidizes, such as magnesium or iron. From the viewpoint of preventing the formation of an oxide film on the metal surface by heating in the atmosphere and inhibiting foaming, it is desirable to heat in a vacuum or in an inert gas atmosphere.
Hereinafter, the present invention will be described in more detail with reference to examples.

Six sheets of 5083 aluminum alloy having a thickness of 1 mm, a width of 30 mm, and a length of 300 mm were prepared. After cleaning the surface of one of the alloy plates, 1% by weight of a powdered titanium hydride foaming agent (particle size 45 μm) based on the weight of the alloy plate was sprayed uniformly while sieving, and then on it, The other alloy plate was stacked with the cleaned surface facing down.
The laminated body thus obtained was rolled and joined using a two-stage roll mill under the conditions of a rolling temperature of 350 ° C. and a reduction rate of 50%. The rolled laminate was cut into half lengths, the cut laminates were superposed, and the laminated laminate was rolled and joined under the same conditions as described above. A 3 mm thick preform was obtained by performing a total of 8 cycles consisting of cutting, overlaying and rolling. When the cut surface of this preform was observed with a microscope, the titanium hydride powder was uniformly dispersed in the matrix of the aluminum alloy, and its particle size was refined to about 10 μm.
The obtained preform is held in a superplastic temperature (550 ° C.) of 5083 aluminum alloy for 10 minutes in an electric furnace to decompose the titanium hydride foaming agent to release hydrogen, thereby producing a foam of aluminum alloy. Got.
When the cross section (rolling direction (RD surface) and direction perpendicular to this (TD surface)) of the obtained aluminum alloy foam was observed with a microscope, the pore shape of the foam was foamed as shown in FIG. It was confirmed that the sphere was crushed in the thickness direction of the body. The foam according to the present invention having discoidal pores obtained by the method of the present invention has a lower thermal conductivity in the thickness direction than the conventional foam having spherical pores when compared with the same porosity. It can be confirmed by a technique such as micromechanics analysis.
Using the aluminum alloy foam obtained by the method of the present invention, as shown in FIG. 3, it has a structure in which an aluminum alloy foam 5 is used on the inside and a polymer foam 6 is attached on the outside. A liquid hydrogen tank can be obtained.

  As an application example of the method for producing a metal foam of the present invention, as a method for producing a metal foam excellent in heat insulation in the thickness direction, which can be used as an inner member of a liquid hydrogen tank. Can be used.

It is a schematic diagram which shows one aspect | mode of the method of this invention. It is a microscope picture of the cross section of the metal foam obtained by the method of this invention. It is a schematic diagram which shows the application example of the metal foam obtained by the method of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Metal plate 2 Foaming agent powder 3 Rolling machine 4 Liquid hydrogen 5 Metal foam 6 Polymer foam

Claims (2)

Preparing a plurality of metal plates made of superplastic metal and a powdery foaming agent, and sandwiching the foaming agent between the plurality of metal plates;
Rolling the plurality of metal plates sandwiching the foaming agent, joining the plurality of metal plates to each other, and obtaining a preform; and
Heating the preform at a superplastic temperature of the superplastic metal to decompose and foam the foaming agent;
A method for producing a metal foam, comprising: Obtaining the preform further comprises:
Cutting the plurality of metal plates joined to each other; and
A step of superimposing the cut metal plates and rolling the superposed metal plates;
The manufacturing method according to claim 1, comprising the step of containing at least once.

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