JP2021134110A - Manufacturing method of foam glass, and foam glass - Google Patents

Abstract

To provide foam glass free from discomfort, even when mixed in soil.SOLUTION: In steps for manufacturing foam glass by a foam glass manufacturing apparatus 1, a mixing agitation step by a mixing agitation part 6 is constituted so that a pigment is mixed and agitated with crushed and pulverized raw material glass. Further, the pigment mixed in the mixing agitation step is 0.4-1.0 wt.%, and iron oxide is 0.5-2.0 wt.%. The wt.% mixing ratio of the iron oxide to the pigment is 1.0-2.0.SELECTED DRAWING: Figure 1

Description

The present invention relates to, for example, a method for producing foamed glass used for agricultural materials and crime prevention gravel.

Conventionally, foamed glass recycled from waste glass has been mixed with agricultural soil for the purpose of improving air permeability and drainage.

For example, a technique for producing foamed glass formed by a plurality of porous layers by mixing waste glass powder, clay powder, woody carbon powder, and a foaming agent in a predetermined ratio and firing them is disclosed. (See Patent Document 1).

However, this foamed glass is formed only in gray in color. Therefore, this foamed glass has a problem that its appearance is impaired when it is mixed with agricultural soil whose basic color is brown. Many consumers who have a vegetable garden in a general household place importance on the appearance of the soil when purchasing.

Further, when used as a crime prevention gravel, the white or gray crime prevention gravel has a demerit that the sunlight is reflected and the gravel feels dazzling, and the appearance is further spoiled by being exposed to wind and rain. From such a background, there has been a demand for foamed glass having a color that is inconspicuous even when mixed with soil.

Japanese Unexamined Patent Publication No. 2006-315914

In view of the above-mentioned problems, it is an object of the present invention to provide a method for producing foamed glass that does not give a sense of discomfort even when mixed in soil.

The present invention is a method for producing foamed glass, which comprises a mixing stirring step of adding an additive to crushed glass powder and mixing and stirring, and a firing step of firing the mixed and stirred mixed and stirred product. The method is a foamed glass manufacturing method for manufacturing colored foamed glass by mixing pigments in the mixing and stirring step.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a method for producing an effervescent glass that does not give a sense of discomfort even when mixed in soil.

The schematic block diagram of the foam glass manufacturing apparatus. Foam glass manufacturing flow chart.

The present inventor has invented a method for producing foamed glass that does not give a sense of discomfort even when mixed in soil. Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a schematic configuration diagram of a foamed glass manufacturing apparatus 1 for carrying out the foamed glass manufacturing method of the present invention.

The foamed glass manufacturing apparatus 1 includes a raw material charging unit 2 for charging the glass waste material as a raw material, a primary crushing unit 3 for crushing the charged glass waste material, and a powdered glass powder obtained by further finely crushing the crushed glass waste material. A crushing unit 4 as a body, a primary sieving unit 5 for removing foreign substances contained in glass powder, and a stirring and mixing unit 6 for stirring and mixing the sieving glass powder together with various additives to form foamed glass. An intermediate product is provided between the fired portion 7 for firing the foamed glass, the secondary crushed portion 8 for crushing the foamed glass after firing, and the secondary sieving section 9 for sieving the foamed glass after crushing. It is provided with a transport unit 10 (10a to 10 g) for transport.

The raw material charging section 2 transfers the charged glass waste material to the primary crushing section 3 in a certain amount. The raw material input unit 2 can store the glass waste material as a raw material, such as a hopper, and transfers the glass waste material to the primary crushing unit 3 automatically or by an artificial operation as needed. It may be a configuration. A certain amount of waste glass material transported from the raw material charging unit 2 is transported to the charging port of the primary crushing unit 3 by a transport unit 10a composed of a belt conveyor.

The primary crushing unit 3 crushes the glass waste material transferred from the raw material input unit 2 to a particle size within a certain range (for example, 6 mm or less). As the primary crushing unit 3, for example, a roller rotation type crusher that sandwiches and grinds glass waste material by rotational compression of vertical rotation with the direction of gravity as the rotation axis can be used. The crushed glass waste material discharged from the primary crushing section 3 is conveyed to the input port of the crushing section 4 by the transport section 10b configured by the belt conveyor.

The crushing unit 4 further crushes the glass waste material crushed by the primary crushing unit 3 into glass powder. It is desirable that the glass powder has a particle size of 200 mm or less. The crushing unit 4 has a configuration in which crushing is performed by lateral rotation with the rotation axis substantially horizontal. For example, a ball mill that grinds an object by a compressive force generated when a plurality of ceramic balls collide with each other can be used. .. The glass powder discharged from the crushing section 4 is conveyed to the input port of the primary sieving section 5 by the conveying section 10c composed of the belt conveyor.

The primary sieving section 5 sifts and removes foreign matter mixed in the glass powder and glass waste material remaining without being crushed. The glass waste material to be removed preferably has a particle size larger than 200 μm. The glass powder discharged from the primary sieving unit 5 is conveyed to the inlet of the stirring and mixing unit 6 by the conveying unit 10d composed of the belt conveyor.

The stirring and mixing unit 6 mixes the foam material, the heavy metal inhibitor, the pigment, and iron oxide with the glass powder, and stirs the glass powder so that the distribution becomes uniform. As the stirring / mixing unit 6, for example, a rotary mixing / stirring machine in which glass powder, foam material, heavy metal inhibitor, pigment, and iron oxide are simultaneously charged into the mixer and mixed and stirred by rotary motion can be used. The blending ratio at this time is, for example, glass powder (94 to 97% by weight), foam material (0.4 to 0.5% by weight), heavy metal inhibitor (2 to 3% by weight), pigment (0.4% by weight). ~ 1.0% by weight) and iron oxide (0.5 to 2.0% by weight) are supplied to the stirring and mixing section 6, and mixing and stirring are performed. The mixture discharged from the stirring and mixing section 6 is conveyed to the inlet of the firing section 7 by the transport section 10e composed of the belt conveyor.

The firing unit 7 melts the mixed and stirred foamed glass material with heat of 650 ° C. to 850 ° C. and fires it to produce foamed glass. As the firing unit 7, for example, a continuous firing method can be used in which the foamed glass material is transferred by the transport unit 10 (belt conveyor) and continuously fired by a burner to generate a plate-shaped foamed glass. When the continuous firing method is used, each step can be divided into a preheating step, a melting step, a firing step, and a slow cooling step, and different temperature settings can be made for each step. The foamed glass discharged from the firing unit 7 is transported to the secondary crushing unit 8 by the transport unit 10f composed of a belt conveyor.

The secondary crushing unit 8 crushes the fired foam glass to a specified particle size (particle size 15 mm to 25 mm) for a product. For the secondary crushing unit 8, for example, a crusher method in which the foamed glass is dropped from above and the fallen foamed glass is sandwiched between blades and crushed can be used. The foamed glass discharged from the secondary crushing section 8 is transported to the secondary sieving section 9 by a transport section 10g composed of a belt conveyor.

The secondary sieve separation unit 9 removes crushed foamed glass having a particle size that does not meet the product standard, such as removing one having a particle size larger than 25 mm. In this way, a foamed glass satisfying the standard is obtained.

FIG. 2 is a manufacturing flow of the foamed glass manufactured by the foamed glass manufacturing apparatus 1.

As a raw material for foamed glass, waste glass that has been used and recovered is used with a thickness of about 15 mm. In the raw material charging step, the waste glass material is charged into the raw material charging unit 2 (step S1). Then, a certain amount of waste glass material is transferred to the primary crushing unit 3 automatically or manually. It is preferable that most of the glass waste material to be introduced is a transparent glass waste material that does not affect the color of the foamed glass as the final product.

In the primary crushing step, the glass waste material transferred by the raw material input section 2 is crushed by the primary crushing section 3 to a particle size of 6 mm or less, which is the maximum crushable particle size of the crushing section (step S2).

In the crushing step, the glass waste material crushed in the primary crushing step is crushed by the crushing unit 4 into a glass powder having a particle size of 200 μm or less which is easy to stir and mix with the additive (step S3). Since the crushed glass powder has a fine particle size, it is preferable that the crushed glass powder is stored or transferred so as not to scatter. A preferred method for transferring the glass powder is a spin flow conveyor that moves the powder or granular material while rotating it.

In the primary sieving step, the primary sieving section 5 removes foreign substances that have not been crushed to 200 μm or less in the crushing step (step S4). The glass waste material having a large particle size that has not been crushed can be collected and re-injected into the raw material charging unit 2 to be used as a raw material for glass powder.

In the mixing step, the mixing and stirring unit 6 mixes an additive foaming agent, a heavy metal inhibitor, a black pigment, and iron oxide with the glass powder that has been pulverized and sieved (step S5).

As the foaming agent, either an organic foaming agent or an inorganic foaming agent may be used. As the organic foaming agent, for example, ADCA (azodicarbonamide), DPT (N, N'-dinitropentamethylenetetramine), OBSH (4,4'-oxybisbenzenesulfonylhydrazide) can be used. As the inorganic foaming agent, for example, hydrogen carbonate or carbonate can be used.

As the heavy metal inhibitor, a heavy metal insolubilizer such as magnesite, which does not adsorb and elute heavy metals, can be used.

As the black pigment, for example, a composite oxide pigment typified by an iron-chromium type or an infrared reflective material can be used. The amount of the black pigment added is preferably 0.5 to 1.0% by weight because the color of the foamed glass after firing is a natural color even when mixed with the soil.

As the iron oxide, for example, iron oxide for coloring prepared for coloring can be used. The amount of iron oxide added is preferably 0.5 to 2.0% by weight because the color of the foamed glass after firing is a natural color even when mixed with the soil. Further, it is more preferable that the mixed weight ratio of iron oxide to the black pigment is 1.0 to 2.0. Further, the average particle size of the black pigment and iron oxide to be added is preferably 0.25 to 6.0 μm from the viewpoint of its dispersibility and the influence on the foaming phenomenon in the firing step.

In the stirring step, the mixing and stirring unit 6 stirs the mixed glass powder and various additives so as to be uniformly dispersed (step S6).

In the mixing step and the stirring step, each work step may be performed by different devices, or the stirring step may be performed after mixing various additives with the glass powder by one device. Various additives may be mixed while stirring with the device.

In the firing step, the firing unit 7 melts and fires the mixed and stirred foamed glass raw material (step S7). At this time, the foamed glass after slow cooling by the foaming agent mixed as an additive has a thickness of about 60 mm. By melting the foamed glass raw material once, solidifying it again, and firing it, the additives and pigments can be dispersed more uniformly, and uneven physical properties and uneven color of the foamed glass product can be reduced. As for the firing temperature in the firing step, the temperature inside the firing section 7 is maintained at 650 to 850 degrees. If it deviates from this temperature range, the foaming phenomenon of the foamed glass raw material becomes unsuitable, and the absolute dry specific gravity becomes unsuitable in the foamed glass product after firing.

In the secondary crushing step, the fired foamed glass is crushed by the secondary crushing unit 8 to a size suitable for a product (step S8).

Then, in the secondary sieving step, the secondary sieving unit 9 sifts the foamed glass after the secondary crushing so as to conform to the product standard (step S9). In the secondary sieving process, the corners of the foamed glass are scraped by using a rotary sieving machine, and the shape becomes more suitable as a product.

By using iron oxide, the foamed glass produced through the above steps is colored brown, which does not give a sense of discomfort when mixed with soil, as compared with foamed glass containing only black pigment or a mixture of brown pigment. NS. Further, by using iron oxide, the strength of the foamed glass is improved, and the suitability as a crime prevention gravel is improved.

Further, by setting the firing temperature in the range of 650 to 850 degrees, the foaming phenomenon is appropriately performed, and the absolute dry specific gravity, which is an important characteristic of the foamed glass, is in the appropriate range.

Further, by using iron oxide, it is possible to finish the color and texture that are close to the color of soil such as dark brown and dark brown that is close to black and do not cause discomfort even on the soil. That is, in places where it is difficult to obtain the desired color, such as the color of the pigment changing and brown changing to green at high temperatures during firing by simply using a pigment, after firing by mixing iron oxide. The desired color can be obtained.

Further, by using black as the pigment, the foamed glass can be finished in a dark color. That is, with colors other than black, the color of the pigment changes at high temperatures during firing, making it difficult to obtain the desired color such as dark brown, but by using a black pigment, the color of the finished foam glass Can be brought closer to black or dark brown that is close to black.

Further, by using both the above-mentioned iron oxide and the black pigment, it is possible to finish the product in black and dark brown while taking advantage of the brownish color of iron oxide.

Further, since the pigment to be mixed in the mixing and stirring step is 0.4 to 1.0% by weight and the iron oxide is 0.5 to 2.0% by weight, it is good to utilize both the color of iron oxide and the pigment. Foamed glass of various colors and textures can be obtained.

Further, since the weight% mixing ratio of iron oxide to the pigment is 1.0 to 2.0, it is possible to prevent the color of iron oxide from losing to the pigment. In particular, even when a black pigment is used, it is possible to prevent the color of iron oxide from losing to the pigment.

Further, since the average particle size of the pigment to be mixed is 0.25 μm to 0.6 μm, it is possible to stir the glass powder well, and it is possible to finish the foamed glass having high color uniformity as a whole without unevenness. ..

Further, since the firing temperature in the firing step is 650 to 850 degrees, it is possible to obtain good foamed glass by satisfactorily melting and firing the glass powder while making the best use of the color of iron oxide.

Since the foamed glass has an absolute dry specific gravity of 0.35 to 0.5 g / cm3 and a water absorption of 5 to 20%, it is possible to obtain colored foamed glass having good color and texture.
[Example 1]

A transparent glass waste material having an average thickness of about 15 mm was put into a raw material hopper capable of storing about 4 m3 of the glass waste material, and transferred to a conveyor by a vibration cutting machine provided at the bottom of the hopper.

The transferred glass waste material was crushed by using a roller rotary crusher in which the glass waste material was sandwiched and crushed by rotational compression so that the particle size of the glass waste material after crushing was 6 mm or less.

The crushed glass waste material was put into a crusher together with a plurality of ceramic balls, and the crusher was rotated. As a result, the glass waste material was crushed to a particle size of 200 μm or less by the compressive force generated when the ceramic balls collide with each other to obtain glass powder.

The glass powder was put into an automatic sieving machine, and only the glass powder having a particle size of 200 μm or less was extracted.

In a rotary mixing stirrer, the extracted glass powder, foaming agent (designated by the Glass Foaming Materials Business Cooperative) was 0.8% by weight, magnesite was 2.0% by weight, and the average particle size was 0.5 μm. Add 0.5% by weight of a certain black pigment (Black 6340 manufactured by Asahi Kasei Kogyo) and 0.5% by weight of iron oxide (KN-320 manufactured by Toda Kogyo Co., Ltd.) having an average particle size of 0.27 μm, and stir for about 15 minutes. Then, it was used as a raw material for foamed glass.

The agitated foamed glass raw material was transferred on a belt conveyor and fired continuously for about 30 minutes by a burner. The firing temperature was adjusted so that the temperature inside the firing furnace was 650 ° C. or higher and 850 ° C. or lower.

The fired foam glass was crushed by a crusher crusher so that the particle size of the foam glass was 15 to 25 mm. Then, the crushed foamed glass was sieved by using a rotary sieving machine while scraping the corners of the foamed glass.

After sieving, the foamed glass is collected and has a water absorption rate (5 to 20% passes), an absolute dry specific density (0.35 to 0.5 g / cm3 passes), and a color (if it is not noticeable when mixed with soil). Various evaluations were performed: ⊚, 〇 if the foamed glass could be discriminated by gazing, and ×) if the foamed glass could be clearly discriminated.
[Example 2]

Same as in Example 1 except that the black pigment (Black 6340 manufactured by Asahi Kasei Co., Ltd.) to be added in the mixing step was 1.0% by weight and the iron oxide (KN-320 manufactured by Toda Kogyo Co., Ltd.) was 1.0% by weight. Foam glass was manufactured and evaluated.
[Example 3]

In the mixing step, foaming was performed in the same manner as in the examples except that the black pigment (Asahi Kasei Kogyo Co., Ltd., Black 6340) to be added was 1.0% by weight and the iron oxide (Toda Kogyo Co., Ltd., KN-320) was 2.0% by weight. Glass was manufactured and evaluated.
[Example 4]

In the mixing step, foaming was performed in the same manner as in the examples except that the black pigment (Asahi Kasei Kogyo Co., Ltd., Black 6340) to be added was 0.5% by weight and the iron oxide (Toda Kogyo Co., Ltd., KN-320) was 2.0% by weight. Glass was manufactured and evaluated.
[Comparative Example 1]

In the mixing step, 1.0% by weight of a brown pigment (Brown 4123, manufactured by Asahi Kasei Kogyo Co., Ltd.) having an average particle size of 1.5 μm was used as an additive instead of a black pigment. Further, the iron oxide to be added (manufactured by Toda Kogyo Co., Ltd., KN-320) was set to 2.0% by weight. Other than that, foamed glass was produced and evaluated in the same manner as in Examples.
[Comparative Example 2]

Iron oxide was not added in the mixing step. Other than that, foamed glass was produced and evaluated in the same manner as in Examples.
[Comparative Example 3]

In the mixing step, the average particle size of the black pigment to be added was changed to 0.7 μm (Asahi Kasei Kogyo Co., Ltd., Black3250), the addition amount was 0.46% by weight, and iron oxide was not added. Other than that, foamed glass was produced and evaluated in the same manner as in Examples.

Table 1 shows the colors of the pigments used in each of the Examples and Comparative Examples, the amount of the pigment added, the amount of iron oxide added, and the evaluation results.

As shown in the evaluation results, the foamed glass to which the black pigment and iron oxide were added had a good color evaluation. In addition, the water absorption rate and absolute dry specific density also met the product regulations. On the other hand, in Comparative Example 1 in which the brown pigment was used, the color became too bright and became a conspicuous color when mixed with soil. Further, Comparative Example 2 and Comparative Example 3 to which iron oxide was not added turned green during firing. Further, in Comparative Example 1 and Comparative Example 3 in which the average particle size was not in a preferable range, the absolute dry specific density and / or the water absorption rate did not meet the product regulations.

The present invention is not limited to the configuration of the above-described embodiment, and many embodiments can be obtained.
For example, in this embodiment, the entire process is carried out by an apparatus operated by a program, but the sieving step, the mixing step, and the like may be carried out manually.

The present invention can be used in the industry of producing foamed glass used as agricultural soil and security gravel.

1 ... Foamed glass manufacturing equipment 2 ... Raw material input unit 3 ... Primary crushing unit 4 ... Crushing unit 5 ... Primary sieve separation unit 6 ... Mixing and stirring unit 7 ... Baking unit 8 ... Secondary crushing unit 9 ... Secondary sieve separation unit

Claims (7)

A mixing and stirring step in which an additive is added to crushed glass powder to mix and stir.
A method for producing foamed glass, which is a method for producing porous foamed glass by a firing step of firing the mixed and stirred mixed mixture.
A foamed glass manufacturing method for producing colored foamed glass by mixing a pigment and iron oxide in the mixing and stirring step. The pigment to be mixed in the mixing and stirring step is 0.4 to 1.0% by weight.
The method for producing foamed glass according to claim 1, wherein the iron oxide is 0.5 to 2.0% by weight. The foamed glass production method according to claim 2, wherein the weight% mixing ratio of the iron oxide to the pigment is 1.0 to 2.0. The method for producing foamed glass according to claim 1, 2 or 3, wherein the pigment to be mixed has an average particle size of 0.25 μm to 0.6 μm. The method for producing foamed glass according to any one of claims 1 to 4, wherein the pigment is a black pigment. The method for producing foamed glass according to any one of claims 1 to 5, wherein the firing step is a firing temperature of 650 to 850 degrees. Manufactured by the manufacturing method according to any one of claims 1 to 6.
The absolute dry specific density is 0.35-0.5 g / cm3,
Effervescent glass with a water absorption rate of 5 to 20%

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