KR101174203B1 - Recovering Method of Methyl MethAcrylate from Waste Artificial Marvel - Google Patents

Abstract

The present invention relates to a method of recovering methyl methacrylate from waste artificial marble, and more particularly, to install a vacuum pump to make a reactor, a condenser, a separator, and the like to improve the thermal efficiency and to obtain the methyl methacrylate. Provided are an apparatus and a method for recovering methyl methacrylate from waste artificial marble capable of maximizing recovery at recovery.

Description

Apparatus and method for recovering methyl methacrylate from waste artificial marble {Recovering Method of Methyl MethAcrylate from Waste Artificial Marvel}

The present invention relates to a method of recovering methyl methacrylate from waste artificial marble, and more particularly, by installing a vacuum pump to make a reactor, a condenser, a separator, and the like in a vacuum state to increase thermal efficiency and the methacrylate. The present invention relates to an apparatus and a method for recovering methyl methacrylate from waste artificial marble capable of maximizing recovery in recovering methyl acid.

As is well known, artificial marble is a prominent building material recently produced around 300,000 tons worldwide, and has a market size of about 600 billion yuan. In addition, the domestic production of artificial marble is more than 100,000 tons, and has a market of about 250 billion won, combined with domestic and export.

The artificial marble currently widely used in Korea is an organic artificial marble made of a mixture of an acrylic resin called methyl methacrylate (hereinafter referred to as 'MMA') and an inorganic material (ie, aluminum hydroxide) that is effective for flame retardant. The mixing ratio is 30 to 45% by weight of MMA, 45 to 65% by weight of inorganic fillers and very small amounts of additives are used.

In addition, since aluminum hydroxide has good characteristics to enhance and generate strength and wear resistance of artificial marble, almost all of them are used as inorganic fillers in artificial marble products produced in Korea.

Artificial marble prepared in the mixing ratio is processed to the required size after manufacturing and used as the top plate of the sink or other articles, a large amount of scrap and dust is generated in the process, the scrap and dust can not be used for other commercialization Most of them are disposed of.

The disposal method is a simple landfill or discarded by incineration, causing secondary soil pollution. Recently, a method of recovering alumina through a calcination process has been proposed, but MMA corresponding to petroleum has a disadvantage of being lost by combustion.

On the other hand, Japanese Patent Application Laid-Open No. JP2006-206638 proposes a decomposition method for recovering inorganic fillers and thermosetting resins from artificial marble waste. The decomposition method is a method of dissolving the thermosetting resin in the critical state by separating the artificial marble waste into water or an organic solvent and raising the temperature and pressure of about 180 ~ 370 ℃, the purity of the recovered MMA and inorganic filler Has the disadvantage of falling.

Therefore, there is a need for a study of a recovery method capable of treating a large amount of waste artificial marble while improving the purity of the recovered MMA and inorganic filler.

The present invention provides an apparatus and a method for recovering methyl methacrylate from waste artificial marble that can improve the thermal efficiency and maximize the recovery of MMA by making the interior of the reactor, the condenser and the separator in a vacuum state. have.

Another object of the present invention is to provide an apparatus and a method for recovering methyl methacrylate from waste artificial marble capable of removing odors such as odor generated when recovering MMA.

The present invention for achieving the above object is a device for recovering methyl methacrylate from waste artificial marble, the storage hopper for storing the waste artificial marble powder raw material, and the waste artificial marble powder raw material stored in the storage hopper A reactor for receiving and pyrolyzing methyl methacrylate and water, a condenser for condensing methyl methacrylate and water pyrolyzed in the reactor, a separator for separating the condensed methyl methacrylate and water from each other, and the separator A purity regulator for adjusting the purity of the methyl methacrylate separated from and connected to the reactor, the condenser and the separator, respectively, and vacuuming the interior of the reactor to remove waste artificial marble powder from methyl methacrylate at low temperature. The separation according to the pumping operation of the vacuum pump and the vacuum pump to be thermally decomposed into water Characterized in that it comprises a odor and moisture remover to remove odor and water generated in the air.

In another aspect, the present invention is a method for recovering methyl methacrylate from the waste artificial marble, the step of thermally decomposing the waste artificial marble powder stored in the storage hopper with methyl methacrylate and water, the thermally decomposed methacryl Condensing methyl acid and water, separating the condensed methyl methacrylate and water from each other, and adjusting the purity of the separated methyl methacrylate; Thermally decomposing the waste artificial marble powder raw material into methyl methacrylate and water at a low temperature by vacuuming the inside of the reactor to which the waste artificial marble powder raw material is supplied in the process of thermal decomposition with methyl acid and water; It further comprises the step of removing the odor and water generated in the process of separating methyl acrylate and water from each other All.

The present invention not only improves the thermal efficiency of the reactor by installing a separate vacuum pump, but also increases the recovery rate of MMA extracted from the separator to the maximum, and also has the advantage of removing odors such as odors remaining in the separator. .

1 is a view showing the configuration of a device for recovering methyl methacrylate from waste artificial marble according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings an embodiment of the present invention will be described. In the following detailed description, exemplary embodiments of the present invention will be described in order to accomplish the above-mentioned technical problems. And other embodiments which may be presented by the present invention are replaced by descriptions in the constitution of the present invention.

In the present invention, by connecting a separate vacuum pump to a conventional reactor, a condenser and a separator to make the interior of the reactor in a vacuum state to be pyrolyzed at a low temperature, and also to increase the recovery rate of water and MMA in the reactor to the maximum. An apparatus and method for recovering methyl methacrylate from waste artificial marble may be provided.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view showing the configuration of an apparatus for recovering MMA from the waste artificial marble to be implemented in the present invention.

As shown in FIG. 1, the apparatus for recovering MMA from the waste artificial marble of the present invention includes a storage hopper 10, a reactor 12, a condenser 16, a separator 20, a purity regulator 26, and It comprises a vacuum pump 22 and the water and odor remover 24.

The storage hopper 10 is a hopper for storing a powder raw material of waste artificial marble that is pulverized in a powder form through a pretreatment process.

The reactor 12 receives the powder raw material of the waste artificial marble introduced from the storage hopper 10 and stirs and heats the powder raw material to the heat source transmitted from the heater 14 surrounding the outer diameter, and has a different crystal structure. Means of pyrolysis with water. At this time, the temperature for thermally decomposing the powder raw material of the waste artificial marble into MMA and water is made at about 200 ℃ ~ 300 ℃, in the present invention according to the operation of the vacuum pump 22, the air pressure inside the reactor 12 is "0 By making the vacuum so as to be able to thermally decompose the powder raw material of the waste artificial marble into MMA and water at a lower temperature, approximately 100 ℃ to increase the thermal efficiency in the reactor (12).

The condenser 16 is a means for condensing through the cooling water circulated and supplied from the cooling water circulation system by receiving the MMA in the gaseous state thermally decomposed in the reactor 12.

The separator 20 is a means for separating MMA and water condensed through the condenser 16 from each other.

The purity adjuster 26 is a means for adjusting the purity of the MMA separated from the water through the separator 20. At this time, an additive is added to the purity adjuster 26 to help adjust the purity of the MMA. As the kind of the additive, it is preferable to use any one of sodium carbonate (Na ₂ CO ₃ ), sodium sulfate (Na ₂ SO ₄ ) or potassium carbonate (k ₂ CO ₃ ).

The MMA whose purity is adjusted by the purity adjuster 26 is recovered through the filter 28 in a state where impurities are completely filtered.

On the other hand, the vacuum pump 22 is a means for pumping the gas present in the reactor 12, the condenser 16 and the separator 20 into a vacuum state, wherein the pumping of the vacuum pump 22 Through the operation, the thermal efficiency in the reactor can be increased, and the moisture remaining in the reactor 12 can be absorbed as much as possible to increase the water recovery rate.

That is, when the pumping operation of the vacuum pump 22 is made, all the gas present in the reactor 12 is sucked into a vacuum state in which the air pressure becomes "0", and the waste artificial introduced into the reactor 12 in this state. When pyrolyzing the powder raw material of marble can be thermally decomposed into MMA and water at a low temperature of approximately 100 ° C. due to low air pressure, rather than a temperature of 200 ° C. to 300 ° C. as in the prior art, thereby improving thermal efficiency in the reactor 12. It can be.

In addition, when the pumping operation of the vacuum pump 22 is made, the inside of the reactor 12 may absorb not only gas but also moisture remaining in the reactor 12, thus increasing the water recovery rate inside the reactor 12. do.

In addition, the vacuum pump 22 is also configured to be connected to the separator 20 separating the MMA and water to absorb the odor and residual moisture such as odor remaining in the separator 22 to discharge to the moisture and odor remover 24. do.

As mentioned above, the moisture and odor remover 24 receives and removes odors and moisture sucked from the separator 20 according to the pumping operation of the vacuum pump 22.

Hereinafter, a method for recovering methyl methacrylate from waste artificial marble according to the present invention will be described.

When recovering MMA from the waste artificial marble, first, a predetermined amount of waste artificial marble powder raw material is supplied into the reactor 12 through the storage hopper 10 in which the powder raw material of the waste artificial marble is stored, and then the reactor 12 ) To operate the vacuum pump 22 in a sealed state to make the vacuum pressure of the reactor 12 and the condenser 16 to be "0", and then, to the reactor 12 through the heater 14 When heated, the powdered raw material of waste artificial marble introduced into the reactor 12 is thermally decomposed into MMA and water at a temperature of 100 ° C., which is relatively low due to the low atmospheric pressure inside the reactor 12. The thermally decomposed MMA and water are passed through the condenser 16 in a gasified state and then condensed.

At this time, the water remaining in the reactor 12 is absorbed to the maximum in the process of the pumping operation of the vacuum pump 22 to increase the water recovery rate in the reactor 12.

Next, the condensed MMA and water are introduced into the separator 20, separated from each other, the MMA is introduced into the purity regulator 26, and the water is discharged to an external treatment facility. At this time, the moisture or odor remaining in the separator 20 is discharged to the water and odor remover 24 according to the pumping operation of the vacuum pump 22.

Next, the MMA introduced into the purity adjuster 26 is purified by an additive introduced into the purity adjuster 26, and then recovered through a filter 28 in a state in which foreign matter is filtered.

10: storage hopper 12: reactor
14: heater 16: condenser
20: separator 22: vacuum pump
24: moisture and odor eliminator 26: purity regulator

Claims (3)

In the device for recovering methyl methacrylate from waste artificial marble,
A storage hopper for storing the waste artificial marble powder raw material;
A reactor for receiving the waste artificial marble powder material stored in the storage hopper and pyrolyzing it with methyl methacrylate and water;
A condenser for condensing the thermally decomposed methyl methacrylate and water in the reactor;
A separator for separating the condensed methyl methacrylate and water from each other;
A purity adjuster for adjusting the purity of the methyl methacrylate separated in the separator;
A vacuum pump connected to the reactor, the condenser and the separator, respectively, to vacuum the inside of the reactor to pyrolyze the waste artificial marble powder material into methyl methacrylate and water;
Apparatus for recovering methyl methacrylate from the waste artificial marble, characterized in that it comprises a odor and moisture remover to remove the odor and water generated in the separator according to the pumping operation of the vacuum pump.
The method of claim 1,
The purity regulator recovers methyl methacrylate from the waste artificial marble, characterized in that any one of an additive is added from sodium carbonate (Na ₂ CO ₃ ), sodium sulfate (Na ₂ SO ₄ ), or potassium carbonate (k ₂ CO ₃ ). Device.
In the method of recovering methyl methacrylate from waste artificial marble,
Thermally decomposing the waste artificial marble powder stored in the storage hopper into methyl methacrylate and water;
Condensing the thermally decomposed methyl methacrylate and water;
Separating the condensed methyl methacrylate and water from each other;
Adjusting the purity of the separated methyl methacrylate;
In the process of thermally decomposing the waste artificial marble powder raw material into methyl methacrylate and water, the inside of the reactor to which the waste artificial marble powder raw material is supplied is vacuumed so as to thermally decompose the waste artificial marble powder raw material into methyl methacrylate and water. Making a step;
The method of recovering methyl methacrylate from the waste artificial marble characterized in that it further comprises the step of removing the odor and water generated in the process of separating the methyl methacrylate and water from each other.

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