JP2007181965A - Method for classifying plastic mixture - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for efficiently classifying plastic pieces (A) made of an acrylic resin and plastic pieces (B) made of another resin whose true specific gravity is different within 0.15, as an absolute value, from that of the plastic pieces (A). <P>SOLUTION: In the method for classifying the plastic pieces (A) and the plastic pieces (B), a plastic mixture containing the plastic pieces (A) of true specific gravity ρA which are made of the acrylic resin and the plastic pieces (B) of true specific gravity ρB which are made of the resin other than the acrylic resin is added into a liquid (L) of specific gravity ρL, and air bubbles are introduced into the liquid (L). (a) The absolute value of difference between ρA and ρB is 0.15 or below, and (b) ρL is 0.9-1.0ρA (when ρA<ρB) or 0.9-1.0ρB (when ρA>ρB). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for separating a plastic mixture including a plastic piece (A) made of an acrylic resin and a plastic piece (B) made of another resin having a small specific gravity difference between the plastic piece (A).

It is known that an acrylic resin undergoes thermal decomposition to depolymerize with high purity to its constituent monomer, methyl methacrylate (hereinafter referred to as “MMA”).
When plastic molded products mainly made of acrylic resin used in automobiles, signboards, home appliances, personal computers, etc. are crushed and plastic pieces are collected, in addition to plastic pieces made of acrylic resin, polyethylene (PE), polypropylene From other resins such as (PP), polystyrene (PS), vinyl chloride resin (PVC), vinyl chloride resin containing plasticizer (PVC compound), cyclopolyolefin (COP), polyethylene terephthalate (PET), polycarbonate (PC), etc. The plastic piece becomes mixed.

When the plastic piece made of acrylic resin and the plastic piece made of another resin are pyrolyzed as they are without separation, the following problems arise.
(1) Wasteful energy is required to thermally decompose other than acrylic resin.
(2) When PVC or PVC compound is included, the apparatus is damaged by chloride generated from PVC or PVC compound.
(3) When PVC or PVC compound is contained, chloride generated from the PVC or PVC compound is mixed in an acrylic monomer obtained by depolymerizing the acrylic resin, and the quality is deteriorated.
(4) When an acrylic resin and another resin, such as PE, PP, PC, or PET, are thermally decomposed, the piping is closed due to a wax component or a high-boiling point substance generated therefrom.

Therefore, in order to obtain a high-quality monomer efficiently from an acrylic resin, it is necessary to remove other resins as much as possible before thermal decomposition.
A wet specific gravity method is known as a method for separating a plastic piece made of an acrylic resin and a plastic piece made of another resin. In the wet specific gravity method, the specific gravity of two types of plastic pieces to be separated is ρ1 and ρ2 (where ρ1 <ρ2), and the specific gravity of the liquid is ρL, ρ1 <ρL <ρ2. This is a method using a liquid. According to the wet specific gravity difference method, when the absolute value of the difference between ρ1 and ρ2 is greater than 0.15, two types of plastic pieces can be separated. However, when the absolute value of the difference between ρ1 and ρ2 is 0.15 or less, the specific gravity difference is small and accurate separation cannot be performed.

A plastic piece made of PE, PP, COP, PS, PET, or PVC can be separated from the plastic piece made of acrylic resin by the wet specific gravity method.
On the other hand, as a plastic piece that cannot be separated from a plastic piece made of acrylic resin by the wet specific gravity method, PC or PVC compound (for example, a material obtained by adding a plasticizer or other additives to PVC and processing into a tube, a gasket, etc. Hereinafter, a plastic piece made of “PVC-C”) may be mentioned.

Since the specific gravity of acrylic resin and PC is almost the same, these plastic pieces cannot be separated by the conventional wet specific gravity differential method.
The specific gravity of PVC is about 1.40 to 1.45, and the difference from the specific gravity of acrylic resin is large. These plastic pieces can be separated by a conventional wet specific gravity differential method. However, since PVC-C contains a plasticizer, the specific gravity is smaller than that of PVC, and hence the specific gravity difference with the acrylic resin is small. Therefore, the plastic piece made of acrylic resin and the plastic piece made of PVC-C are the conventional wet type. It cannot be separated by the specific gravity difference method.

As another separation method, a method of separating bubbles by introducing bubbles into the liquid is known.
(1) A plastic mixture that is heavier than water and close in specific gravity is poured into water containing microbubbles having a bubble diameter of 100 μm or less, and the plastic close to the specific gravity of water is attached to the surface by the adhesion of the microbubbles to the plastic surface. A method of separating plastics by utilizing the fact that the apparent specific gravity when bubbles are attached becomes smaller than that of water and floats, and other plastics having a higher specific gravity than water are settled (Patent Document 1).
(2) A method of introducing PVC into water or salt water to separate PVC from mixed plastic (Patent Document 2).
(3) A method of separating PVC from mixed plastic by introducing bubbles into water or salt water in the presence of a soap press soap and a flotation agent (Patent Document 3).

In the example of Patent Document 1, separation of PS and PET is described. Although the specific gravity of the resin to be divided is not described in detail in Patent Document 1, the specific gravity of PS is usually 1.05 to 1.18, and the specific gravity of PET is usually 1.6 to 1.9. . The minimum absolute value of the specific gravity difference between the two resins is 0.42. Moreover, the specific gravity (1.0) of the used water is 0.85 to 0.95 times the smaller specific gravity (PS) of both resins.
However, when water is used as the liquid used for separation as in the method (1), the absolute value of the difference between the specific gravity of the plastic piece made of acrylic resin and the specific gravity of the plastic piece made of another resin is 0.15 or less. In the case of (for example, a plastic piece made of acrylic resin and a plastic piece made of PC or PVC-C), these plastic pieces cannot be separated.

Patent Document 2 does not describe the specific gravity difference between the PVC and the resin to be separated and the specific gravity of the liquid used for separation. For example, when the PVC and the acrylic resin are separated, it is not described how much the specific gravity of the liquid is set.
In the method (3), there is a problem that the separation efficiency is poor and a soap press soap and a flotation agent are required.
Japanese Patent Laid-Open No. 11-34056 Japanese Patent Laid-Open No. 50-37874 JP 50-32274 A

  Therefore, an object of the present invention is to provide a plastic piece (A) made of an acrylic resin and a plastic piece made of another resin whose absolute specific gravity difference between the plastic piece (A) is 0.15 or less ( It is to provide a method for efficiently separating B).

The plastic mixture fractionating method of the present invention comprises a plastic mixture containing a plastic piece (A) of true specific gravity ρA made of acrylic resin and a plastic piece (B) of true specific gravity ρB made of other resin excluding acrylic resin. It is a method for separating a plastic piece (A) and a plastic piece (B) by introducing bubbles into the liquid (L) having a specific gravity ρL, and satisfying the following conditions (a) and (b) It is characterized by satisfying.
(A) The absolute value of the difference between ρA and ρB is 0.15 or less.
(B) ρL is 0.9 to 1.0 times the smaller true specific gravity of ρA and ρB.

When the plastic piece (A) is composed of two or more types of plastic pieces (A) having different specific gravities, the smallest specific gravity among them is ρAmin, and ρL is 0, which is the true specific gravity of the smaller one of ρAmin and ρB. 9 times to 1.0 times.
When the plastic piece (B) is composed of two or more types of plastic pieces (B) having different specific gravities, the smallest specific gravity among them is ρBmin, and ρL is 0, which is the true specific gravity of the smaller one of ρA and ρBmin. 9 times to 1.0 times.

In the method for fractionating a plastic mixture of the present invention, it is preferable that the following condition (c) is further satisfied.
(C) The plastic piece (A) and the plastic piece (B) are plastic pieces that pass through a sieve with an opening of 30 mm and do not pass through a sieve with an opening of 2 mm.

In the method for fractionating a plastic mixture of the present invention, it is preferable that the following condition (d) is further satisfied.
(D) The thickness of the plastic mixture layer under the liquid (L) before introducing bubbles is 5 cm or less.

  According to the method for fractionating a plastic mixture of the present invention, the absolute value of the difference in true specific gravity between the plastic piece (A) made of acrylic resin and the plastic piece (A) is 0.15 or less. The plastic piece (B) can be efficiently separated.

In the method for fractionating a plastic mixture according to the present invention, a plastic piece (A) having a true specific gravity ρA made of an acrylic resin and a plastic piece (B) having a true specific gravity ρB made of another resin excluding the acrylic resin, and ρA A plastic mixture in which the absolute value of the difference between ρB and ρB is 0.15 or less is put into a liquid (L) having a specific gravity ρL, and bubbles are introduced into the liquid (L) to give plastic pieces (A) and plastic pieces (B) Is characterized in that, as the liquid (L), a liquid in which ρL is previously adjusted to 0.9 to 1.0 times the true specific gravity of the smaller one of ρA and ρB is used.
The true specific gravity of the plastic piece and the specific gravity of the liquid are values obtained by dividing each density (g / cm ³ ) by the density of water 1.0 (g / cm ³ ).

  The plastic piece (A) is a plastic piece made of acrylic resin. One type of acrylic resin may be sufficient and the mixture of two or more types of acrylic resins from which specific gravity differs may be sufficient.

The acrylic resin is a polymer obtained by polymerizing acrylic monomers, or a copolymer obtained by polymerizing acrylic monomers and other monomers. The acrylic resin may be a crosslinked resin.
Acrylic monomers include acrylic acid, methacrylic acid, and esters thereof. Examples of the acrylate ester include methyl acrylate, ethyl acrylate, and propyl acrylate. Examples of the methacrylic acid ester include MMA, ethyl methacrylate, propyl methacrylate and the like.
Examples of other monomers include maleic anhydride, styrene, α-methylstyrene, acrylonitrile and the like.

It is known that an acrylic resin can recover the monomer constituting the resin by thermal decomposition. In the monomer unit (100% by mass) constituting the acrylic resin, the monomer is recovered with high purity. What has 50-100 mass% of acryl-type monomer units is preferable, and what has 70-100 mass% is especially preferable.
In addition, the acrylic resin preferably has 50 to 100% by mass of MMA units among monomer units (100% by mass) constituting the acrylic resin in terms of recovering the monomer in high yield, and has 70 to 100% by mass. Those are particularly preferred.

  The plastic piece (A) may contain a filler. Examples of the filler include aluminum hydroxide, silica, calcium carbonate, glass fiber, talc, and clay. Further, the plastic piece (A) may contain various additives other than the filler. Examples of additives include pigments, dyes, reinforcing agents, various stabilizers, and the like.

  The plastic piece (B) is a resin other than an acrylic resin, and is made of a resin whose absolute value of the difference between ρA and ρB is 0.15 or less. Examples thereof include PC, PVC-C, and PS. One type of other resin may be sufficient and a 2 or more types of mixture may be sufficient as it. When there are two or more types of other resins, all of them must be a combination of resins that are more likely to have bubbles than an acrylic resin or a combination of resins that are difficult to attach. In the case of two or more types of resins, when at least one type is more likely to have bubbles than acrylic resin and at least one type is less likely to have bubbles than acrylic resin, plastic pieces (A) and plastic pieces (B ) Cannot be separated.

  The plastic piece (B) may contain various additives other than the filler and the filler. Examples of the various additives other than the filler and the filler include those exemplified for the plastic piece (A).

  The plastic mixture may include resin pieces other than the plastic piece (A) and the plastic piece (B). From the viewpoint of thermally decomposing the acrylic resin plastic piece (A) separated from the plastic mixture and recovering the monomer with high purity, the resin other than the plastic piece (A) and the plastic piece (B) as 100% by mass of the plastic mixture is used. The content of the piece is preferably 10% by mass or less. Examples of the other resin pieces include COP, PP, PE, PET, PVC, and the like.

In the fractionation method of the present invention, it is necessary to satisfy the following conditions (a) and (b), and it is preferable to satisfy (c). Furthermore, it is preferable that the following condition (d) is satisfied.
(A) The absolute value of the difference between ρA and ρB needs to be 0.15 or less, preferably 0.13 or less. When the absolute value of the difference between ρA and ρB is greater than 0.15, the effect of separation due to the difference in the ease of bubble attachment does not appear significantly. The lower limit of the absolute value of the difference between ρA and ρB is zero. The true specific gravity of the plastic piece is calculated by measuring the true density (g / cm ³ ) according to JIS K-7112 C method (floating and sinking method).

Examples of the form of the plastic piece (A) and the plastic piece (B) include crushed pieces obtained by crushing discarded plastic molded articles; pellets, relatively small molded articles, and the like.
(C) The plastic piece (A) and the plastic piece (B) are preferably plastic pieces that pass through a sieve having an opening of 30 mm and do not pass through a sieve having an opening of 2 mm. When the plastic piece does not pass through a sieve having an opening of 2 mm, it becomes difficult to float regardless of the type of resin, and the separation efficiency is improved. When the plastic piece passes through a sieve having an opening of 30 mm, the mass of the plastic piece becomes smaller than the buoyancy caused by the attached bubbles, so that the plastic piece to be floated can obtain sufficient buoyancy and the separation efficiency is improved.

The liquid (L) is not particularly limited as long as it does not dissolve the plastic piece (A) and the plastic piece (B), but water is preferable from the viewpoint of handleability.
When water is used as the liquid, the specific gravity ρL of water can be adjusted by (i) a method for dissolving a water-soluble substance in water, (ii) a method for changing the temperature of the water, etc. Therefore, the method (i) is preferable. As the water-soluble substance, sodium chloride, calcium chloride, and glycerin are preferable in terms of handling and cost.

  (B) ρL needs to be 0.9 to 1.0 times the smaller true specific gravity of ρA and ρB, and preferably 0.95 to 1.0 times. By making ρL 0.9 times the true specific gravity of the smaller one of ρA and ρB, the plastic piece that is likely to be bubbled easily moves to the upper layer of the liquid (L), which is convenient for separation. . By making ρL 1.0 times or less of the true specific gravity of the smaller one of ρA and ρB, it becomes easier to separate the plastic pieces that are less likely to be bubbled to the lower layer of the liquid (L), which is convenient for separation. .

The specific gravity of the liquid is calculated by putting the liquid to be measured into a 100 cm ³ graduated cylinder, measuring the mass with a precision balance, and dividing the mass (g) by the volume (100 cm ³ ). The temperature is the temperature at which the plastic mixture is fractionated.

  (D) It is preferable that the thickness of the plastic mixture layer under the liquid (L) before introducing bubbles is 5 cm or less. When the thickness of the plastic mixture layer is 5 cm or less, the plastic piece that originally settles is not lifted by the floating plastic piece, so that the separation efficiency is improved.

Examples of the method for introducing bubbles into the liquid (L) include a mechanical stirring method, a gas blowing method, a pressurizing method, a depressurizing method, or a combination thereof. Among these, the equipment cost is low, and the bottom of the separation tank The gas blowing type by bubbling from is preferred.
The bubbles are preferably air or nitrogen from the viewpoint of ease of handling and cost.

The bubble diameter can be adjusted by the shape of the gas discharge port, the discharge speed, etc., but the bubble diameter is preferably 2 mm or less. If the bubble diameter is too large, the number of bubbles adhering to the plastic piece is reduced, and the plastic piece to be suspended cannot obtain sufficient buoyancy, which may reduce the separation efficiency. There is no particular lower limit for the bubble diameter.
The total amount (volume) of bubbles introduced into the liquid is preferably at least twice the volume of the plastic mixture (volume of the plastic itself). When the amount of bubbles is set to be twice or more the volume of the plastic mixture, the plastic piece to be suspended obtains sufficient buoyancy, and the separation efficiency is improved. The amount of bubbles is preferably 20 times or less with respect to the volume of the plastic mixture. If the amount of bubbles increases too much, there is a risk that the bubbles may stick to the plastic pieces that are difficult to attach bubbles and float.

Examples of the separation tank include a tank having an arbitrary shape such as a square, a cylinder, or a polygon. A bubble introducing device is installed in the separation tank.
Separation may be performed batchwise (batchwise) or continuously.

  When the batch method is used, the plastic mixture may be put in the separation tank first, followed by the liquid (L), and the liquid (L) is put in the separation tank first, and then the plastic mixture is put. May be. In any case, the plastic mixture and the liquid (L) are then mixed well by a method such as stirring. And a bubble is introduce | transduced with the bubble introduction apparatus installed in the decomposition tank. After the introduction of the air bubbles and standing, the plastic pieces (supernatant) collected in the upper layer are first collected. Then, the lower layer plastic piece (precipitate) is collected.

  In the case of continuous operation, bubbles are introduced by a bubble introduction device while supplying the plastic mixture to the separation tank containing the liquid (L). In order to improve the dispersion of bubbles, the entire separation tank may be stirred with a stirrer. The plastic pieces that have floated up are continuously discharged from the upper part of the separation tank together with the liquid (L) and collected. The lower plastic piece is continuously discharged and collected by a take-out device installed in the separation tank.

  In the method for separating a plastic mixture according to the present invention described above, a plastic piece (A) of true specific gravity ρA made of acrylic resin, and a plastic piece (B) of true specific gravity ρB made of other resin excluding acrylic resin, And a plastic mixture in which the absolute value of the difference between ρA and ρB is 0.15 or less is placed in a liquid (L) having a specific gravity ρL, and bubbles are introduced into the liquid (L) to easily cause bubbles. Is collected in the upper layer, and when plastic pieces that are difficult to foam are collected in the lower layer to separate the plastic pieces (A) and plastic pieces (B), ρL is the smaller of ρA and ρB in advance as a liquid (L) Since the liquid adjusted to 0.9 to 1.0 times the true specific gravity of the liquid is used, it is not the separation using the difference between ρL and ρA and ρB as in the past, but the separation based on the ease of attachment of bubbles. But Done. Therefore, the plastic piece that is likely to be bubbled easily moves to the upper layer of the liquid (L), and the plastic piece that is difficult to be bubbled easily moves to the lower layer of the liquid (L). As a result, the plastic piece (A) and the plastic piece (B) having a small difference in true specific gravity can be efficiently separated.

  In the method for separating a plastic mixture of the present invention, a plastic piece (A) made of acrylic resin (hereinafter referred to as “acrylic resin piece”) and a plastic piece (B) made of PC (hereinafter referred to as “PC piece”). ), And a plastic piece (B) made of an acrylic resin piece and PVC-C (hereinafter referred to as “PVC-C piece”), and an acrylic resin piece and a PS plastic piece (B) ( Hereinafter, it is particularly effective for the classification of “PS piece”.

When the acrylic resin piece and the PC piece are compared, bubbles are more likely to be attached to the PC piece. Therefore, when the acrylic resin piece (ρA) and the PC piece (ρB) are separated, the specific gravity (ρL) of the liquid (L) should be 0.9 to 1.0 times the smaller of ρA and ρB. Thus, the PC piece that is easily attached with bubbles moves to the upper layer, and the acrylic resin piece that is difficult to attach bubbles moves to the lower layer.
Specifically, by this method, 90% by mass or more of the acrylic resin piece (100% by mass) contained in the plastic mixture before separation can be recovered from the lower layer of the liquid (L), and Reduce the mass% of PC pieces contained in the plastic mixture (100% by mass) recovered from the lower layer to less than half the mass% of PC pieces contained in the plastic mixture (100% by mass) before separation. Can do.

When comparing an acrylic resin piece and a PS piece, bubbles are more likely to be attached to the PS piece. Therefore, when the acrylic resin piece (ρA) and the PS piece (ρB) are separated, the specific gravity (ρL) of the liquid (L) should be 0.9 to 1.0 times the smaller of ρA and ρB. Thus, the PS piece that is easily attached with bubbles moves to the upper layer, and the acrylic resin piece that is less likely to attach bubbles moves to the lower layer.
Specifically, by this method, 90% by mass or more of the acrylic resin piece (100% by mass) contained in the plastic mixture before separation can be recovered from the lower layer of the liquid (L), and Reduce the mass% of PS pieces contained in the plastic mixture (100% by mass) recovered from the lower layer to less than half the mass% of PS pieces contained in the plastic mixture (100% by mass) before separation. Can do.

Since both the PC piece and the PS piece are more likely to have air bubbles than the acrylic resin piece, mixed plastic of the acrylic resin piece (ρA) and the plastic piece (ρB) composed of two types of PC piece and PS piece can also be separated. When the acrylic resin piece (ρA) and the mixture of the PC piece and the PS piece (the specific gravity of the resin having a small specific gravity of the PC piece and the PS piece is ρBmin) are separated, the specific gravity (ρL) of the liquid (L) By setting 0.9 to 1.0 times the smaller one of ρA and ρBmin, the PC and PS pieces that are likely to be bubbled move to the upper layer, and the acrylic resin pieces that are less likely to be bubbled move to the lower layer.
Specifically, by this method, 90% by mass or more of the acrylic resin piece (100% by mass) contained in the plastic mixture before separation can be recovered from the lower layer of the liquid (L), and The total mass% of the PC piece and the PS piece contained in the plastic mixture (100% by mass) recovered from the lower layer part of the PC piece and the PS piece contained in the plastic mixture (100% by mass) before separation. It can be reduced to less than half of the total mass%.

When the acrylic resin piece and the PVC-C piece are compared, bubbles are more likely to be attached to the acrylic resin piece. Therefore, when the acrylic resin piece (ρA) and the PVC-C piece (ρB) are separated, the specific gravity (ρL) of the liquid (L) is 0.9 times or more of the smaller one of ρA and ρB. Acrylic resin pieces that are likely to be bubbled move to the upper layer, and PVC-C pieces that are less likely to be bubbled move to the lower layer.
Specifically, by this method, 90% by mass or more of the acrylic resin piece (100% by mass) contained in the plastic mixture before separation can be recovered from the upper layer part of the liquid (L), and Half the mass% of the PVC-C pieces contained in the plastic mixture (100 mass%) before fractionation of the mass% of the PVC-C pieces contained in the plastic mixture (100 mass%) recovered from the upper layer. Can be reduced to:

  EXAMPLES Hereinafter, although an Example demonstrates this invention further more concretely, this invention is not limited by these Examples.

(Plastic pieces used)
Acrylic resin piece:
An acrylic resin piece was obtained by crushing a sheet (weight average molecular weight 700,000 (polystyrene equivalent)) of a homopolymer consisting of 100% by mass of MMA unit obtained by cast polymerization and having a thickness of 3 mm with a crusher. . There were two types of sheets, a transparent sheet and a blue sheet.

PVC-C gasket:
A soft vinyl chloride resin compound comprising 63 parts by mass of a vinyl chloride resin (weight average molecular weight 97,000, manufactured by Aldrich, product number 346772), 30 parts by mass of acetyltributyl citrate, and 7 parts by mass of calcium carbonate (primary particle diameter 0.1 μm). Was processed into a tube shape (light yellow opaque) having an outer diameter (diameter) of 8.5 mm and a thickness of 3.0 mm, and this was cut with scissors to form a cube having a side of about 3 mm.

PC piece:
Polycarbonate (weight average molecular weight 64,000, manufactured by Aldrich, product number 181625).
PS piece:
Polystyrene (weight average molecular weight 280,000, manufactured by Aldrich, product number 182427).
As all the plastic pieces, in a sieving device composed of a two-stage sieve, a sieve that passed through a sieve having a mesh size of 3.5 mm and that did not pass through a sieve having a mesh size of 2.5 mm was used.

[Example 1]
Prepare a plastic mixture consisting of 6.0 g (transparent, polygonal) acrylic resin pieces with a true specific gravity of 1.19 and 4.0 g (transparent, bowl-like) PC pieces with a true specific gravity of 1.20. did. The volume of the plastic mixture was 6.0 / 1.19 + 4.0 / 1.20 = 8.4 cm ³ .
In addition, 41.8 g of glycerin and 21.5 g of water were mixed to prepare a glycerin aqueous solution having a specific gravity of 1.17. The temperature of the aqueous solution was kept at 25 ° C. during fractionation.

First, 10.0 g of the plastic mixture is put into a glass bottle (inner diameter: 3 cm, height: 14.5 cm) having an internal volume of 100 ml, then 63.3 g of glycerin aqueous solution is put, the lid of the glass bottle is closed, and shaken well. When left for about 2 minutes, the entire plastic piece was precipitated at the bottom of the glass bottle. The thickness of the plastic mixture layer was 1.5 cm.
Thereafter, the lid is opened, a rubber hose having an inner diameter of 1 mm is placed in the bottom of the glass bottle, and nitrogen gas is introduced at a rate of 0.1 liter / min for 20 seconds while moving the position of the hose left and right so that air bubbles spread throughout the glass bottle. 3 cm ³ of nitrogen gas was supplied. The volume of nitrogen gas was 33.3 cm ³ /8.4 cm ³ = 4.0 times the volume of the plastic mixture.

Thereafter, the mixture was allowed to stand for about 2 minutes, and the supernatant and the precipitate were separated. Each was sufficiently washed with water and vacuum-dried at 70 ° C. for 12 hours. Each of the supernatant and the precipitate was visually divided into an acrylic resin piece and a PC piece according to the shape of the plastic piece (polygon or bowl), and the respective masses were measured. The results are shown in Table 1.
Among the acrylic resin pieces 6.0 g (100% by mass) contained in the plastic mixture before separation, the amount contained in the precipitate was 5.88 g (98.0% by mass). Of the total 5.93 g (100 mass%) of the precipitate, the acrylic resin piece was 5.88 g (99.2 mass%), and the PC piece was 0.05 g (0.8 mass%).

[Example 2]
Instead of the PC piece, a PVC-C gasket 4.0 g (light yellow opaque) having a true specific gravity of 1.30 is used, and the specific gravity is 1.19 g consisting of 45.0 g of glycerin and 15.0 g of water. The same operation as in Example 1 was performed except that an aqueous glycerin solution was used. The volume of the plastic mixture was 6.0 / 1.19 + 4.0 / 1.30 = 8.1 cm ³ . The thickness of the plastic mixture layer was 1.5 cm. The volume of nitrogen gas was 33.3 cm ³ /8.1 cm ³ = 4.1 times the volume of the plastic mixture.
The acrylic resin piece and the PVC-C gasket were distinguished from each other whether they were transparent or opaque (colored). The results are shown in Table 2.
Of the acrylic resin pieces 6.0 g (100% by mass) contained in the plastic mixture before separation, 5.96 g (99.3% by mass) was contained in the supernatant. Of the total 5.98 g (100 mass%) of the supernatant, the acrylic resin piece was 5.96 g (99.7 mass%), and the PVC-C gasket was 0.02 g (0.3 mass%).

Example 3
Instead of a PC piece, PS piece 4.0 g (transparent) having a true specific gravity of 1.06 was used, blue acrylic resin piece was used instead of a transparent acrylic resin piece, glycerin 10.2 g and water The same operation as in Example 1 was performed except that a glycerin aqueous solution having a specific gravity of 1.04 consisting of 49.8 g was used. The volume of the plastic mixture was 6.0 / 1.19 + 4.0 / 1.06 = 8.8 cm ³ . The thickness of the plastic mixture layer was 1.5 cm. The volume of nitrogen gas was 33.3 cm ³ /8.8 cm ³ = 3.8 times the volume of the plastic mixture.
Distinguishing between the acrylic resin piece and PS was made by whether it was transparent or colored (colored). The results are shown in Table 3.
Of the acrylic resin pieces 6.0 g (100% by mass) contained in the plastic mixture before separation, the amount contained in the precipitate was 5.80 g (96.7% by mass). Of the total 5.90 g (100% by mass) of the precipitate, the acrylic resin piece was 5.80 g (98.3% by mass), and the PS piece was 0.10 g (1.7% by mass).

[Comparative Example 1]
The same operation as in Example 1 was performed except that water (25 ° C.) having a specific gravity of 1.0 was used instead of the glycerin aqueous solution having a specific gravity of 1.17. Even after the nitrogen gas was supplied, the acrylic resin piece and the PC piece were all precipitated, and the two resins could not be separated.

[Comparative Example 2]
The same operation as in Example 2 was performed except that water (25 ° C.) having a specific gravity of 1.0 was used instead of the glycerol aqueous solution having a specific gravity of 1.19. Even after supplying the nitrogen gas, the acrylic resin piece and the PVC-C piece were all precipitated, and the two resins could not be separated.

According to the separation method of the present invention, a plastic piece of an acrylic resin can be efficiently separated from a plastic mixture including a plastic piece of an acrylic resin and a plastic piece of another resin having a similar specific gravity. The fractionation method of the present invention can be used for recycling (manufacturing) monomers by reusing acrylic resin, particularly by thermal decomposition of acrylic resin.

Claims (3)

A plastic mixture containing a plastic piece (A) of true specific gravity ρA made of acrylic resin and a plastic piece (B) of true specific gravity ρB made of other resin excluding acrylic resin is placed in a liquid (L) of specific gravity ρL, A method of separating bubbles from a plastic piece (A) and a plastic piece (B) by introducing bubbles into the liquid (L),
A method for fractionating a plastic mixture, which satisfies the following conditions (a) and (b):
(A) The absolute value of the difference between ρA and ρB is 0.15 or less.
(B) ρL is 0.9 to 1.0 times the smaller true specific gravity of ρA and ρB. The method for fractionating a plastic mixture according to claim 1, further satisfying the following condition (c).
(C) The plastic piece (A) and the plastic piece (B) are plastic pieces that pass through a sieve with an opening of 30 mm and do not pass through a sieve with an opening of 2 mm. The method for fractionating a plastic mixture according to claim 1 or 2, further satisfying the following condition (d):
(D) The thickness of the plastic mixture layer under the liquid (L) before introducing bubbles is 5 cm or less.