JP2009298644A - Method for producing foam glass - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technique capable of reducing the production cost of foam glass. <P>SOLUTION: As shown in Fig.(a), an earth and sand glass material (tertiary earth and sand glass) 20 contains particles 22 of resins among glass particles 21, wherein grains of earth and sand are not shown. This earth and sand glass material 20 is temporarily fired at about 600°C to obtain a temporarily fired body 25 in which particles 26 of carbon replace the particles 22 of resins as shown in (c). This temporarily fired body 25 is finely crushed to obtain crushed powder 30 in which fine particles 31 of carbon replace the particles 26 of carbon as shown in (d). This crushed powder 30 is subjected to concluding firing at about 800°C to obtain foam glass 34 comprising glass 32 and bubbles 33. Since the particles of resins function as a blowing agent, the foam glass can be produced from only ASR without adding a blowing agent. Since it is not necessary to get a blowing agent, the production cost of the foam glass can be reduced. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a method for producing foam glass.

There has been proposed a technology for converting waste glass into foamed glass to effectively use resources (for example, see Patent Document 1).
JP 2005-132714 A (Claim 2)

Claim 2 of Patent Document 1 states that “a crushed glass and at least one component selected from the group consisting of calcium hydroxide, calcium oxide, calcium phosphate, calcium sulfate, calcium carbonate, ferric oxide, ferric sulfate and activated carbon; ,
Melting and foaming at a temperature of 700 ° C. to 1100 ° C., and
At least one component selected from the group consisting of calcium hydroxide, calcium oxide, calcium phosphate, calcium sulfate, calcium carbonate, ferric oxide, ferric sulfate and activated carbon is dispersed in the foamed glass to be produced. The manufacturing method of foam glass. Is described.

  That is, Patent Document 1 is to mix a “foaming agent” composed of a group of calcium hydroxide, calcium oxide, calcium phosphate, calcium sulfate, calcium carbonate, ferric oxide, ferric sulfate and activated carbon into crushed glass. The present invention relates to a technology for producing foamed glass characterized by

That is, in the conventional technology, the procurement cost of the foaming agent is indispensable, and this is a factor that increases the manufacturing cost of the foamed glass.
Therefore, reduction of the manufacturing cost of foam glass is required.

  This invention makes it a subject to provide the technique which can reduce the manufacturing cost of foamed glass.

The invention according to claim 1 uses shredder dust called ASR obtained by cutting a used automobile as a starting material. The starting material is subjected to processing such as sorting, crushed, grain size is adjusted, and glass particles are formed. Preparing an earth and sand glass material mixed with an appropriate amount of resin grains;
A pre-baking step of pre-baking this earth and sand glass material;
It comprises a crushing step of finely crushing the obtained calcined body and crushing the carbon particles contained in the calcined product, and a main calcining step of subjecting the obtained crushed powder to main baking to obtain foamed glass. It is characterized by that.

In the invention according to claim 1, resin particles remain in the earth and sand glass material. This resin is rich in carbon (C) and calcium carbonate (CaCO ₃ ). Carbon is oxidized to carbon dioxide when heat is applied. When heat is applied to calcium carbonate, it decomposes and generates carbon dioxide. This carbon dioxide gas becomes the foaming gas.
That is, it is not necessary to add a foaming agent separately, and it becomes possible to manufacture foamed glass only by ASR, and it is not necessary to procure the foaming agent, so that the manufacturing cost of foamed glass can be reduced.

Furthermore, this invention includes the temporary baking process and the process of crushing the obtained temporary baking body finely. The resin particles are changed to carbon particles by temporary baking, and the carbon particles are crushed into small carbon particles in a crushing step.
Small particles of carbon are dispersed in the obtained pulverized powder. Such a fired body obtained by subjecting the pulverized powder to main firing becomes a high-quality foamed glass in which fine bubbles are uniformly dispersed.

The best mode for carrying out the present invention will be described below with reference to the accompanying drawings.
FIG. 1 is a basic manufacturing flow diagram of foam glass according to the present invention, in which equipment such as an engine, transmission, airbag, tire, battery, fuel, and oil are removed from a used automobile (ST01). Next, it cuts with a shredder (ST02). The obtained shredder dust is generally called ASR (Automobile Shredder Residue).

  The obtained ASR is subjected to sorting processing by applying a known sorting method such as specific gravity sorting (ST03). Although this processing method will be described in detail in the next figure, the third earth and sand glass can be obtained by applying this treatment to earth and sand glass (first and second earth and sand glass). The tertiary earth and sand glass is heated to about 600 ° C. to perform a temporary firing process (ST04). Thus, a temporarily fired body can be obtained, and the temporarily fired body is heated to about 800 ° C. to perform the main firing process (ST05). Thereby, foamed glass can be obtained. Details of the pre-baking process of ST04 and the main baking process of ST05 will be described later.

FIG. 2 is a flowchart for explaining processing such as sorting in detail, and step numbers (ST) are numbered from 11 for convenience. FIG. 3 is a drawing supplementing FIG.
As shown in FIG. 3A, the ASR is composed of, for example, 55% by mass of resin, 20% by mass of metal, and the remaining earth and sand glass (with earth and sand attached to glass).

  From such ASR, most of ferrous metals are excluded by well-known magnetic sorting method, non-ferrous sorting method and specific gravity sorting method, most of non-ferrous metals such as aluminum and copper are excluded by non-ferrous sorting method, Most of them are excluded (ST11). Thus, the primary earth and sand glass is obtained.

  Resin, metal, earth and sand that could not be separated by well-known sorting remain because the resin molding and the antenna are firmly bonded to the glass and the dust is firmly attached. Therefore, as shown in FIG. 3B, the primary earth and sand glass is composed of, for example, 6.3% by mass of resin (residual resin), 12.9% by mass of metal (residual metal), and glass (residual). Including the amount of earth and sand).

Such primary earth and sand glass is crushed (ST12).
This crushing is performed by a blade crusher, a ball mill crusher or other crushers. The principle of the blade crusher is explained in the following figure

  FIG. 4 is a principle diagram of the blade crusher. The blade crusher 10 passes through a base 11 having a built-in motor, a container 12 mounted on the base 11, and a bottom of the container 12. And a crushing blade 14 mounted horizontally on the motor shaft 13 and a lid 15 that closes the upper opening of the container 12.

A primary earth and sand glass 16 indicated by an imaginary line is placed in the container 12. Cover with lid 15,
The crushing blade 14 is rotated horizontally at high speed. Then, the crushing blade 14 collides with the first earth and sand glass 16 and starts crushing and the like.

The primary earth and sand glass 16 contains residual metal, residual resin, residual earth and sand, and glass shown in FIG.
Among them, the residual metal is hard and is not crushed. Since the residual resin is soft, it is shaved and separated into shavings and the remaining resin. Naturally, the shavings are small and the remaining resin is large.
The remaining soil and glass are crushed.

The first sieve is applied in ST13 of FIG. Residual metal and residual resin remain on the sieve. On the other hand, resin shavings, glass particles and earth and sand fall through the sieve. The part which fell is called the secondary earth and sand glass. Resin shavings are called re-residual resin.
That is, when the crushed earth and sand glass is passed through the first sieve, all of the residual metal and most of the residual resin are separated and excluded. And the secondary earth and sand glass which consists of the remaining glass grain, a re-residue resin, and residual earth and sand is obtained.

In ST14, the second earth and sand glass is passed through the second sieve. The second sieve has smaller eyes than the first sieve.
Residual resin having a too small particle size, glass particles having a too small particle size, and earth and sand having a too small particle size pass through the second sieve and are excluded. The moderately sized glass particles, the re-residue resin and the residual earth and sand remaining on the second sieve are referred to as tertiary earth and sand glass.
As shown in FIG. 3C, the tertiary earth and sand glass is composed of 0.1 to 3% by mass of a residual resin and glass particles (including residual earth and sand).

  The particle size of the tertiary earth and sand glass is preferably in the range of 50 to 500 μm, and most preferably 250 μm. The first sieve mesh (mesh) and the second sieve mesh (mesh) are determined so as to obtain such a particle size.

  Next, the case where a ball mill type crusher is used instead of the blade type crusher at ST12 in FIG. 2 will be described. A ball mill type crusher is a device that puts a lot of hard balls inside a rotating drum and crushes the primary earth and sand glass with these balls, and its crushing performance is much higher than that of a blade type crusher. Therefore, when the primary earth and sand glass is crushed with a ball mill type crusher, most of the soft resin may be finely crushed.

Most of the finely crushed resin passes through the first sieve and the second sieve. As a result, there is a possibility that the ratio of the resin occupied in the tertiary earth and sand glass is significantly lower than the resin ratio of 0.1% by mass shown in FIG. This makes the resin ratio too low.
Therefore, when adopting a ball mill type crusher, it is necessary to devise such as shortening the crushing time so that the resin ratio becomes 0.1% by mass or more, and the crushing work becomes troublesome.
In this respect, a blade-type crusher is preferable because the crushing time can be sufficiently secured and the crushing operation becomes easy.

The pre-baking process performed to the obtained 3rd earth-and-sand glass (it is also called earth-and-sand glass material) is demonstrated below.
FIG. 5 is a flowchart for explaining the pre-baking process, and FIG. 6 is a supplementary explanatory view of FIG.
As shown in FIG. 6A, in the third earth and sand glass 20, resin particles (re-residual resin whose particle size is adjusted) 22 are mixed between the glass particles 21 and the glass particles 21. Sediment grains were omitted.

  By the way, generally a plasticizer, a stabilizer, a filler, and other additives are added to the resin. Among them, the filler is a mixture for saving resin raw materials. A typical example of the filler is calcium carbonate.

  If the tertiary earth and sand glass 20 shown in FIG. 6A is baked at about 800 ° C. for 60 minutes, the glass particles 21 are melted and the calcium carbonate contained in the resin particles 22 is reduced. It is thermally decomposed into calcium (calcium oxide) and carbon dioxide. As a result, large bubbles 101 are generated in the glass 102 as shown in FIG.

  Compared to the case where a large number of small bubbles are dispersed, the bubbles 101 are inevitably unevenly distributed when the bubbles 101 have a large diameter. Therefore, the quality of the foam glass 103 shown in (b) is low. It is required to improve the quality, and the method will be described below.

  In FIG. 5, the tertiary earth and sand glass is temporarily fired at about 600 ° C. (ST15). Thus, a temporarily fired body can be obtained. As shown in FIG. 6B, the temporarily fired body 25 is obtained by mixing carbon particles 26 between the glass particles 21 and the glass particles 21. That is, the resin particles 22 were baked and carbonized. Such a pre-fired body 25 is fragile unlike the main fired body. Therefore, the temporarily fired body 25 can be finely crushed (ST16).

By this crushing, the carbon particles 26 are also crushed into small particles. As shown in FIG. 6D, the obtained crushed powder 30 is obtained by dispersing small particles 31 of carbon between the glass particles 21 and the glass particles 21.
When the crushed powder 30 is baked at about 800 ° C., a high-quality foamed glass 34 in which a large number of bubbles 33 are appropriately dispersed in the glass 32 as shown in FIG. 6E can be obtained.

  That is, the tertiary earth and sand glass 20 shown in FIG. 6A is not immediately fired (mainly fired), but is subjected to a temporary firing process, and the obtained temporary fired body is finely crushed, and the obtained crushed material is obtained. By subjecting the powder to a main baking treatment, a high-quality foam glass 34 in which bubbles are evenly dispersed can be obtained.

  At this time, it is not necessary to add a foaming agent such as calcium carbonate. That is, the resin particles 22 contained in the tertiary earth and sand glass 20 were used as substitutes for the foaming agent. As a result, it is not necessary to procure a foaming agent, and the manufacturing cost of foamed glass can be reduced.

Incidentally, chromium (Cr) and trivalent chromium (Cr ⁺³ ) are mixed in paint and plating applied to the body of an automobile. It is expected that a part of such chromium (Cr) or trivalent chromium (Cr ⁺³ ) is mixed in the crushed powder 30 shown in FIG. It is known that chromium (Cr) and trivalent chromium (Cr ⁺³ ) are oxidized and changed to toxic hexavalent chromium.
It is necessary to prevent the generation of this toxic substance, hexavalent chromium. In other words, instead of the process of FIG. 6D to 6E, the process described below is recommended.

FIG. 7 is a diagram for explaining the main baking process. In (a), the crushed powder 30 is filled into the lidless container 35 whose upper surface is open. The crushed powder 30 includes glass particles 21, small carbon particles 31, and chromium-based particles 36. The chromium-based grains 36 are chromium (Cr), trivalent chromium (Cr ⁺³ ), or a mixture thereof.

Next, as shown in (b), heating is performed at about 800 ° C. from above the lidless container 35. Then, the glass particles on the upper surface are melted to form the glass layer 37. After this, the small particles 31 of carbon combine with surrounding oxygen (O ₂ ) and change to carbon dioxide (CO ₂ ).

Since this reaction is performed in a sealed space, the space below the glass layer 37 is an oxygen-free atmosphere or a reducing atmosphere. Chromium (Cr) or trivalent chromium (Cr ⁺³ ) placed in an oxygen-free atmosphere or reducing atmosphere does not proceed with oxidation, so there is no ^fear of changing to hexavalent chromium (Cr ⁺⁶ ).

Therefore, as shown in (c), the main baking is performed from the periphery of the lidless container 35 as a whole at about 800 ° C. By heating at this time, the glass particles become molten glass 38, and bubbles 39 of carbon dioxide gas are dispersed therein. These bubbles 39 are further expanded by heating.
The foamed glass 40 obtained by cooling after the main baking treatment includes a large number of bubbles 42 in the glass 41 as shown in FIG. The chromium-based grains 36 are contained in the form of harmless chromium (Cr) or trivalent chromium (Cr ⁺³ ).

The main firing process described in FIG. 7 is summarized in the form of a flow.
FIG. 8 is a flowchart for explaining the main baking process, in which crushed powder is filled into a container without a lid (ST17), and the upper surface is heated (ST18). As a result, a glass layer is formed, and a reducing atmosphere is formed under the glass layer. Next, the whole is heated at about 800 ° C. (ST19). Then, carbon dioxide (CO ₂ ) expands, bubbles are evenly dispersed, and foamed glass containing chromium in the form of harmless chromium (Cr) or trivalent chromium (Cr ⁺³ ) is obtained. it can.

In the above description, the pre-baking temperature is about 600 ° C. and the main baking temperature is about 800 ° C., but the pre-baking temperature is selected from an appropriate temperature below the melting point (500 to 650 ° C.) based on the melting point of the glass for automobiles. The main firing temperature may be an appropriate temperature higher than the melting point (a temperature selected from 700 to 900 ° C.).
Moreover, the main baking time is preferably 60 to 180 minutes, and most preferably 60 minutes.

  The present invention is suitable for a technique for producing foamed glass from shredder dust called ASR.

It is a basic manufacturing flowchart of the foam glass which concerns on this invention. It is a flow figure explaining processing, such as sorting, in detail. It is drawing which supplements FIG. It is a principle diagram of a blade type crusher. It is a flowchart explaining a temporary baking process. FIG. 6 is a supplementary explanatory diagram of FIG. 5. It is a figure explaining this baking processing. It is a flowchart explaining this baking process.

Explanation of symbols

  20 ... earth and sand glass material (tertiary earth and sand glass), 21 ... glass grain, 22 ... resin grain, 25 ... pre-fired body, 26 ... carbon grain, 30 ... crushed grain, 31 ... small grain of carbon, 34 ... Foam glass.

Claims (1)

Using shredder dust called ASR, which is obtained by cutting used automobiles, as a starting material, the starting material is subjected to processing such as sorting, crushing, particle size is adjusted, and glass particles are mixed with an appropriate amount of resin particles A process of preparing earth and sand glass material,
A pre-baking step of pre-baking this earth and sand glass material;
Crushing step of finely crushing the obtained calcined product, crushing the carbon particles contained in the calcined product,
A method for producing foam glass, comprising: a main firing step of subjecting the obtained crushed powder to main firing to obtain foamed glass.

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