JP7318810B2 - Recycling method of waste polystyrene products - Google Patents

Description

The present invention relates to a method for recycling waste polystyrene products.

Among the plastics discharged from factories and homes, there are various types of plastics. Among them, polystyrene is used in many fields such as food packaging trays, cases of electric appliances and information equipment, heat insulation materials, and cushioning materials. , and accounts for a large proportion of waste plastics. Therefore, it is an important technical problem to recycle the waste polystyrene discharged in large amounts as a resource, and various recycling methods have been proposed for this purpose.

There is material recycling as a recycling method of waste polystyrene. In material recycling, waste polystyrene is collected, washed, pulverized, and pelletized to produce polystyrene products again. Various proposals have been made for material recycling of waste polystyrene (see Patent Document 1, for example).

JP 2020-7424 A

However, the material recycling that manufactures polystyrene products by the remelting method has a problem that the strength of polystyrene is lowered because polystyrene is reduced in molecular weight by repeating the melting of polystyrene. In order to obtain the same strength as polystyrene formed by polymerizing naphtha-derived styrene monomer (hereinafter also referred to as naphtha-derived polystyrene), for example, naphtha-derived polystyrene should be reinforced by adding

Therefore, it is possible to manufacture recycled polystyrene such that polystyrene obtained by recycling used polystyrene products, so-called waste polystyrene products (hereinafter also referred to as recycled polystyrene) exhibits the same strength as naphtha-derived polystyrene. A new recycling method for waste polystyrene products is desired.

An object of the present invention is to provide a method for recycling waste polystyrene products that can produce recycled polystyrene having improved strength compared to polystyrene produced by material recycling. Another object of the present invention is to provide a recycling method capable of suppressing the deterioration of the color of polystyrene due to the deterioration of the color of the polystyrene due to resin burning caused by the material recycling of waste polystyrene products.

As a result of intensive research to solve the above problems, the present inventor found that the above problems can be solved by using chemical recycling to regenerate styrene monomer by pyrolyzing recovered waste polystyrene. , have completed the present invention.

That is, the present invention includes the following aspects.
[1] A step of thermally decomposing waste polystyrene products to obtain recycled styrene monomer from waste polystyrene,
A method for recycling waste polystyrene products, comprising:
[2] The method for recycling waste polystyrene products according to [1], wherein the waste polystyrene products include uncolored polystyrene products and colored polystyrene products.
[3] The method for recycling waste polystyrene products according to [1] or [2], wherein the waste polystyrene products are pulverized to obtain a pulverized waste polystyrene product, and the pulverized product is thermally decomposed.
[4] The step of obtaining the recycled styrene monomer comprises:
a step of thermally decomposing waste polystyrene products using a thermal decomposition apparatus;
By supplying the steam generated by the thermal decomposition to a condenser, the gas flare component is removed from the thermal decomposition product in which the oil component containing the recycled styrene monomer and the gas flare component are mixed, and the oil component containing the recycled styrene monomer is obtained. a step of distilling and refining the oil component containing the recycled styrene monomer using a distillation column to improve the purity of the recycled styrene monomer;
The method for recycling waste polystyrene products according to any one of [1] to [3], comprising:
[5] A step of removing solids from the slurry components generated by the thermal decomposition using a separation device, and using the thermal decomposition device for the clarified slurry from which the solids have been removed a step of pyrolyzing,
The method for recycling waste polystyrene products according to [4], further comprising
[6] The method for recycling waste polystyrene products according to [4] or [5], wherein the pyrolyzer is a pyrolyzer using microwaves.
[7] The recycled styrene monomer contains, in addition to the styrene monomer, at least one selected from the group consisting of inorganic substances, aromatic compounds, cyclohexadiene-based compounds, and cyclohexene-based compounds [1] to [6]. 3. A method for recycling waste polystyrene products according to any one of the above.
[8] A step of collecting waste polystyrene products,
a process of thermally decomposing the collected waste polystyrene products to obtain recycled styrene monomer from the waste polystyrene;
a step of polymerizing the recycled styrene monomer to obtain recycled polystyrene; and a step of obtaining a recycled polystyrene product comprising the recycled polystyrene;
A method for recycling waste polystyrene products, comprising:

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a method for recycling waste polystyrene products that can produce recycled polystyrene having improved strength compared to polystyrene produced by material recycling.
In addition, since the present invention does not cause resin burning caused by material recycling of waste polystyrene products, the present invention provides a method for recycling waste polystyrene products that can produce recycled polystyrene in which the deterioration of the color of the resin is suppressed. can do.

BRIEF DESCRIPTION OF THE DRAWINGS It is the schematic which shows one aspect|mode of the recycling method of the waste polystyrene product of this invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram showing one aspect of a process for producing recycled styrene monomer in the method for recycling waste polystyrene products of the present invention. FIG. 3 is a schematic diagram showing another aspect of the manufacturing process of recycled styrene monomer in the method for recycling waste polystyrene products of the present invention.

Hereinafter, the method for recycling waste polystyrene products of the present invention will be described in detail, but the description of the constituent elements described below is an example as one embodiment of the present invention, and is not limited to these contents. .

(Method for recycling waste polystyrene products of the present invention)
The method for recycling waste polystyrene products of the present invention includes the step of thermally decomposing waste polystyrene products to obtain recycled styrene monomer from waste polystyrene.
The recycling method of the present invention is a chemical recycling method for producing styrene monomer, which is a raw material for polystyrene products, from waste polystyrene products.
Waste polystyrene is the recycled styrene monomer of the present invention, polystyrene products made from petroleum-derived styrene monomer, or waste polystyrene products obtained by material recycling.
Furthermore, a preferred embodiment of the method for recycling waste polystyrene products of the present invention includes a method for recycling waste polystyrene products including the following steps 1) to 4).
1) Process of collecting waste polystyrene products (hereinafter also referred to as recovery process)
2) A process of thermally decomposing the collected waste polystyrene products to obtain recycled styrene monomer from the waste polystyrene (hereinafter also referred to as a manufacturing process of recycled styrene monomer).
3) Process of polymerizing recycled styrene monomer to obtain recycled polystyrene (hereinafter also referred to as process of manufacturing recycled polystyrene)
4) obtaining a recycled polystyrene product consisting of recycled polystyrene (
(hereinafter also referred to as the manufacturing process of polystyrene products)
In the present invention, the recycled styrene monomer refers to a recycled styrene monomer, that is, a styrene monomer obtained from waste polystyrene through a recycling process.
In the present invention, recycled polystyrene refers to recycled polystyrene, that is, polystyrene obtained by polymerizing recycled styrene monomers or polystyrene obtained by material recycling.

The recycled polystyrene products (hereinafter also referred to as recycled polystyrene products) obtained in step 4) above are supplied to the market. Thereafter, recycled polystyrene products that are no longer needed and waste recycled polystyrene products such as used recycled polystyrene products are collected again.
The recycled waste polystyrene products collected again are subjected to the thermal decomposition treatment in step 2). Thereby, recycled styrene monomer can be produced again.
Thus, the recycled polystyrene products manufactured through the steps 1) to 4) are again subjected to the steps 1) to 4) to manufacture recycled polystyrene products.
According to the present invention, waste polystyrene products can be repeatedly manufactured into recycled polystyrene products, and a recycling system for waste polystyrene products can be established.

An overview of the recycling method of the present invention will be described with reference to FIG.
The waste polystyrene product 1 is recovered (recovery step A).
The recovered waste polystyrene product is subjected to each process such as a thermal decomposition process, an oil component acquisition process, and a distillation purification process to produce recycled monomer 2 (recycled styrene monomer production process B).
The produced recycled styrene monomer 2 is polymerized to produce recycled polystyrene 3 (process C for producing recycled polystyrene).
Using the manufactured recycled polystyrene 3, various polystyrene products 4 are manufactured (polystyrene product manufacturing process D).
When the manufactured polystyrene product 4 becomes unnecessary, it is used as a waste polystyrene product 1,
It can be used for the recovery step A.
Waste polystyrene product 1 is polystyrene product 4 obtained from the present invention, polystyrene product containing petroleum-derived styrene monomer, or waste polystyrene product obtained by material recycling.
As shown in FIG. 1, according to the recycling method of the present invention, it is possible to establish a recycling system for waste polystyrene products.
Each of the above steps 1) to 4) will be described in detail below.

<Recovery step A>
Collect waste polystyrene products.
Here, waste polystyrene products refer to discarded polystyrene products such as unnecessary polystyrene products and used polystyrene products.
The recovered waste polystyrene products are subjected to the thermal decomposition treatment in step 2) above. 2) above
The waste polystyrene products subjected to the step 2) need not be particularly sorted after recovery, and all the recovered waste polystyrene products can be subjected to the thermal decomposition treatment of the step 2) above.
For example, polystyrene products include colored products, but only uncolored polystyrene products can be used without any restrictions in material recycling. Colored polystyrene products (eg, black polystyrene products) can only be recycled into products with specific uses, such as hangers.
According to the recycling method of the present invention, colored polystyrene products (e.g., black polystyrene products) and non-colored polystyrene products (e.g., black polystyrene products) can be recycled without separating colored polystyrene products (e.g., black polystyrene products) from uncolored polystyrene products. It is possible to produce uncolored recycled polystyrene products from waste polystyrene products including polystyrene products of
According to the recycling method of the present invention, both uncolored polystyrene products and colored (colored) polystyrene products can be subjected to the thermal decomposition treatment in step 2) in a mixed state.
Here, a colored (colored) polystyrene product refers to a polystyrene product combined with a coloring agent such as a pigment for coloring. Modes of combination include, for example, addition to a polystyrene base material, attachment of a colored laminate film, and the like.
According to the present invention, there is no need to separate products by color after collection, and not only uncolored polystyrene products but also colored polystyrene products can be recycled. According to the present invention, it is possible to reduce the labor involved in sorting work after collection. In addition, the recycling utilization rate of waste polystyrene products can be improved, and 100% recycling of styrene in waste polystyrene products can be expected.

<<Pulverization process>>
Before subjecting the collected waste polystyrene products to the thermal decomposition treatment step, a step of pulverizing the waste polystyrene products to obtain a pulverized waste polystyrene product may be further provided, if necessary.
That is, waste polystyrene products may be pulverized to obtain pulverized waste polystyrene products, and the pulverized products may be subjected to the thermal decomposition treatment in step 2) above.

<Manufacturing process B of recycled styrene monomer>
In the present invention, a condensable oil containing a styrene monomer (also referred to as a monomer oil component in the present invention) is obtained from a thermal decomposition product produced by pyrolyzing polystyrene, and the condensable oil is purified. , to obtain recycled styrene monomer. The purity of styrene in the recycled styrene monomer differs depending on the purification method of the recycled styrene monomer.
In the present invention, the monomer oil component refers to an oil component containing a styrene monomer.

Preferred embodiments of the recycled styrene monomer production step B are as follows.
Pyrolyze waste polystyrene products. As a result, thermal decomposition products in which the monomer oil component and the gas flare component are mixed are generated as steam. By condensing and separating the vapor, the gas flare component is removed to obtain the monomer oil component. A styrene monomer is obtained by distilling and refining the monomer oil component. Thus, styrene monomer can be produced from waste polystyrene.
That is, a preferred embodiment of the recycled styrene monomer production process B includes a production process including a thermal decomposition treatment process, an oil component acquisition process, and a distillation purification process.
Furthermore, in the present invention, it is more preferable that the production process includes a separation process after the pyrolysis treatment process.
Each step constituting the recycled styrene monomer manufacturing step B will be described in detail below with reference to FIG.

<<Pyrolysis treatment process>>
The recovered waste polystyrene product 1 is thermally decomposed.
As shown in FIG. 2, when a waste polystyrene product 1 is thermally decomposed using a thermal decomposition apparatus a, steam (cracked gas) 10 is generated. This pyrolysis product obtained as vapor contains a monomer oil component 14 and a gas flare component 15 .
Here, gas flare components refer to gas components and coke components.
The type of pyrolysis apparatus is not particularly limited as long as it can obtain a pyrolysis product containing the monomer oil component 14 and the gas flare component 15 from polystyrene as described above. A device is preferred.

<<<Pyrolysis equipment using microwaves>>>
A method of thermally decomposing polystyrene using a thermal decomposition apparatus using microwaves will be described below.
The term "microwave" means electromagnetic waves with wavelengths between 1 meter and 1 millimeter, or frequencies between 300 MHz (0.3 GHz) and 300 GHz.
Preferably, microwaves suitable for use in the present invention range from about 915 MHz to about 2450 MHz.
It is an electromagnetic wave with a frequency of z.
Microwave sources include, for example, magnetron tubes.

A catalyst is preferably added to the waste polystyrene product to be subjected to the thermal decomposition treatment in order to initiate microwave thermal decomposition of the waste polystyrene product.
Such a catalyst is not particularly limited as long as it absorbs microwaves, transfers heat to the waste polystyrene product, and contributes to the thermal decomposition reaction of the waste polystyrene product, and can be appropriately selected according to the purpose. , the catalyst comprising a compound having high dielectric loss at microwave frequencies.
Alternatively, the catalyst may be a carbonaceous residue from a previous pyrolysis reaction, ceramic beads containing microwave absorbing additives, pellets containing microwave absorbing additives, or combinations thereof. good too. In this case, as a microwave absorbing additive,
Examples include silicon carbide and boron nitride.
Alternatively, the catalyst may be a catalyst comprising a carbon compound containing from about 80% to about 90% by weight carbon, such as graphite.
The catalyst is preferably contained in an amount of 0.5% to 50% by mass, more preferably 0.5% to 5% by mass, in the raw material subjected to thermal decomposition treatment, which is a combination of the catalyst and the waste polystyrene product. More preferably, it is contained in an amount of 0.5% by mass to 2.5% by mass.

The pyrolysis treatment is preferably carried out under conditions where oxygen is not added.
Here, "no oxygen is added" means that no molecular oxygen (O ₂ ) gas is added.
In the thermal decomposition reaction of the present invention, when the oxygen content in the thermal decomposition apparatus is a suitable residual amount for advancing thermal decomposition, the thermal decomposition process is performed without adding molecular oxygen (O ₂ ) gas. is preferably started.
Here, the desired content of oxygen remaining in the pyrolyzer is preferably about 10% by volume or less, more preferably about 5% by volume or less.

The pyrolyzer may be provided with anaerobic means for purging the pyrolyzer.
Anaerobic means include, for example, the above-described inert gas, fluid, and the like.
The fluid may be water.
Inert gases include argon, nitrogen, steam, and the like.
Anaerobic means also include vacuum sources such as vacuum pumps and venturi tubes.
Anaerobic means may be inert gases, fluids, vacuum sources, or combinations thereof as described above.

In the present invention, the steam produced by evaporation of the initial water present in the product purges the atmosphere within the pyrolyzer to enable oxygen-free pyrolysis.
Therefore, in the present invention, the pyrolysis treatment is preferably carried out under a steam purge.
Alternatively, a predetermined amount of water may be added to the waste polystyrene product to ensure proper purging of air due to water evaporation.
Molecular oxygen (O ₂ ) gas is not added into the pyrolyzer, but the waste may contain large amounts of oxygen. In the present invention, the water is allowed to evaporate before the start of the pyrolysis reaction,
The pyrolysis reaction may occur in a steam environment rather than in air, as the steam produced in the pyrolysis unit will expel any air present there as the temperature rises. Once the air has been expelled and the proper temperature and internal pressure have been reached, the pyrolysis unit is sealed. The present invention may be carried out with steam pyrolysis, in which no additional oxygen is introduced, rather than completely oxygen-free pyrolysis in a nitrogen or argon atmosphere, which is usually done as an anaerobic procedure.

Waste polystyrene in the pyrolyzer by absorption of the microwaves on the inner wall of the pyrolyzer and the absorption of the microwaves by the catalyst, using microwaves of sufficient time to allow heat generation and the catalyst. The product is heated to decompose the polystyrene.
The thermal decomposition temperature of waste polystyrene is preferably about 300° C. to about 650° C.,
More preferably from about 300°C to about 450°C.

As shown in FIG. 2, when a waste polystyrene product is thermally decomposed using a thermal decomposition apparatus a using microwaves, the above-described steam (mixture of monomer oil component and gas flare component) 10 is generated. Slurry components remain in the apparatus. The steam 10 is separated into a monomer oil component 14 and a gas flare component 15 by being condensed and separated using a condenser c.
When the waste polystyrene product is thermally decomposed using the thermal decomposition apparatus a, the thermal decomposition treatment may be performed multiple times by the thermal decomposition apparatus as shown in FIG. The steam 10 may be obtained by performing the thermal decomposition process multiple times (in FIG. 3, it is performed twice).

By performing pyrolysis using microwaves, it is possible to apply heat uniformly and efficiently from the inside to the polystyrene in the pyrolysis apparatus, compared to a pyrolysis furnace that uses a normal external heater.
The thermal decomposition rate is high, and the styrene monomer purity in the monomer oil component can be increased.

<< Separation process >>
In the present invention, it is preferable to subject the slurry component 11 generated by the thermal decomposition treatment to a separation step.
In other words, for the slurry component generated by thermal decomposition, a separator is used to separate light liquids such as styrene monomer, styrene oligomer, ethylbenzene, and benzene, as well as carbides (char) and inorganic substances from the slurry component, and solids are separated. It is preferable to thermally decompose the clarified slurry from which the solid matter has been removed again using the thermal decomposition apparatus.
For example, as shown in FIG. 2, when polystyrene is thermally decomposed using a thermal decomposition apparatus a, a slurry component 11 generated in the apparatus is treated using a separation apparatus b. Separation device b separates clarified slurry 12 and solid matter (char/inorganic matter) 13, and then reintroduces clarified slurry 12 into thermal separation device a.
Here, char refers to a carbonaceous by-product generated by thermal decomposition.
The step of obtaining the clarified slurry 12 from the slurry component 11 and charging the clarified slurry 12 into the thermal separator a can be repeated.
The separation device b can remove contaminants unnecessary for recycling contained in waste polystyrene products. Contaminants include, for example, pigments used in waste polystyrene products for coloring polystyrene products, molding components for producing products, and the like.
By adopting a separation process for removing these contaminants, for example, even if colored polystyrene products are to be recycled, recycled styrene monomers with good hue and quality can be produced. The separation step is effective in the recycling method of the present invention for recycling not only uncolored polystyrene products but also colored polystyrene products.
By adding a separation step, a recycled styrene monomer of good quality can be produced at a high yield. Furthermore, it is possible to suppress the accumulation of solids 13 in the pyrolysis apparatus, reduce the number of times of washing the pyrolysis furnace, and continuously produce the monomer oil.

<<Oil component acquisition process>>
Thermal decomposition products produced by thermally decomposing waste polystyrene are separated into a monomer oil component 14 and a gas flare component 15 by condensing and separating using the difference in boiling points. Then, the monomer oil component 14 is supplied to the next distillation purification step.
For example, as shown in FIG. 2, steam 10 generated by pyrolysis is supplied to a condenser c.
The condenser c has a cooling pipe through which cooling water flows, and cools the steam (cracked gas) discharged from the thermal cracker a to condense and separate high boiling point components. In the condenser c, the separated monomer oil component 14, which is a high boiling point component, is supplied to the first distillation column d, and the gas flare component 15, which is a low boiling point component that is not condensed, is discharged outside the container of the condenser.

A step of subjecting the monomer oil component 14 from which the gas flare component 15 has been removed to the thermal cracking unit again may be added before subjecting it to the distillation refining step.
For example, a monomer obtained by separating a dimer component from the monomer oil component 14 using a condenser and subjecting the dimer component to thermal decomposition treatment using a thermal decomposition apparatus By adding the oil component to the remaining monomer oil component excluding the dimer component from the previously obtained monomer oil component 14, the combined monomer oil component can be supplied to the first distillation column d.
Thereby, the yield of recycled styrene monomer can be increased.
In the present invention, the dimer component may include not only dimers but also oligomers such as trimers.

<<Distillation purification process>>
The monomer oil component 14 is purified by distillation using a distillation column to separate the styrene monomer and other components.
For example, as shown in Figure 2, two distillation columns are used. Then, in the first distillation column d, mainly the benzene/toluene/ethylbenzene component 16 is separated from the monomer oil 14, and the remaining component is supplied to the second distillation column e. Next, in the second distillation column e, a dimer component/other (α-methylstyrene, etc.) component 17 is separated to obtain a styrene monomer (so-called recycled styrene monomer 2).
Here, the dimer component may include oligomers such as trimers in addition to dimers, as described above.
The recycled styrene monomer according to the present invention thus obtained is a styrene monomer of good quality. Therefore, the recycled polystyrene produced using the recycled styrene monomer obtained in the present invention is good recycled polystyrene exhibiting strength and hue equivalent to those of naphtha-derived polystyrene.

Further, in the present invention, in the second distillation column e, a step of subjecting the dimer component/other (α-methylstyrene etc.) component 17 separated from the styrene monomer to the thermal decomposition unit again may be added. I do not care.
For example, as shown in FIG. 2, dimer components/other (α-methylstyrene, etc.) components 17 are separated from the second distillation column e.
The separated dimer component/other (α-methylstyrene, etc.) component 17 is supplied again to the thermal decomposition apparatus a. Thus, the dimer component/other (such as α-methylstyrene) component 17
is subjected to thermal decomposition treatment again to obtain additional recycled styrene monomer. When the additionally obtained recycled styrene monomer and the already obtained recycled styrene monomer 2 shown in FIG. 2 are added together, the yield of the recycled styrene monomer can be further increased.

Recycled styrene monomer production process B, in which recycled styrene monomer is produced through the above-described thermal decomposition treatment process, oil component acquisition process, and distillation purification process, is a production method in which the amount of CO ₂ emissions is suppressed.
Therefore, it can be said that the method for recycling polystyrene products of the present invention is a production method with a high life cycle assessment (LCA) evaluation.

<<Characteristics of recycled styrene monomer>>
Although the recycled styrene monomer obtained in the present invention is of good quality, it contains a small amount of impurities within a range that does not adversely affect practical use.
Impurities include toluene, benzene, cumene, dimers, trimers, ethylbenzene, α
Aromatic compounds such as -methylstyrene, n-propylbenzene, phenylacetylene, etc. may not be completely removed and may be slightly contained in the recycled styrene monomer.
Inorganic substances such as silicon, copper, iron, titanium, and carbon may also be contained as impurities.
In addition, as impurities, 1,3-cyclohexadiene, 2-ethyl-1,3-cyclohexadiene, 2-vinyl-1,3-cyclohexadiene, 2-methyl-1,3-cyclohexadiene, 1,4-cyclohexadiene Hexadiene, 2-ethyl-1,4-cyclohexadiene, 2
- Cyclohexadiene compounds such as vinyl-1,4-cyclohexadiene and 2-methyl-1,4-cyclohexadiene, and compounds such as cyclohexene compounds such as cyclohexene and cyclohexenehexane may be slightly contained. .
As the content of the above impurities in the recycled styrene monomer, the upper limit is usually 10
% by mass or less, may be 5% by mass or less, may be 3% by mass or less, or may be 1% by mass or less, and the lower limit is not particularly limited, but is usually greater than 0% by mass. Any combination of these upper and lower limits may be used. The content of impurities in recycled styrene monomer is usually 0
It is more than 10% by mass or less, more than 0% by mass and less than 5% by mass, more than 0% by mass and less than 3% by mass, or more than 0% by mass and less than 1% by mass.
Among them, the upper limit of the content of the inorganic component in the recycled styrene monomer is usually 0.1% by mass or less, may be 0.01% by mass or less, or may be 0.001% by mass or less, and the lower limit is particularly limited. not, but usually greater than 0% by weight. Any combination of these upper and lower limits may be used. The content of inorganic components in recycled styrene monomer is usually 0
More than 0.1% by mass or less, more than 0% by mass and less than 0.01% by mass, more than 0% by mass and less than 0.001% by mass, more than 0% by mass and less than 1% by mass .

<Manufacturing process C of recycled polystyrene>
The obtained recycled styrene monomer is polymerized to obtain recycled polystyrene.
The obtained recycled polystyrene is recycled polystyrene having improved strength compared to polystyrene produced by material recycling, as described above.
The recycled polystyrene thus obtained is polystyrene in which deterioration of hue due to burning of the resin is suppressed.
Polymerization methods for styrene monomer include solution polymerization method, bulk polymerization method, suspension polymerization method, gas phase polymerization method, and the like, and any method can be employed.
The solution polymerization method is, for example, a method in which 5 to 20% of a solvent such as ethylbenzene or toluene having a boiling point of 130° C. to 200° C. is mixed with a styrene monomer and polymerized. In the suspension polymerization method, for example, a dispersant is used in a large amount of water to disperse the styrene monomer as particles, and the polymerization is performed using a catalyst such as peroxide. .

Embodiments of recycled polystyrene obtained by polymerizing recycled styrene monomers may include not only styrene homopolymers but also copolymers of styrene monomers and monomers other than styrene. It may also include rubber-modified polystyrene grafted in the presence of butadiene rubber and the like.

The obtained recycled polystyrene exhibits excellent strength when the strength is evaluated by the following measuring method. Assuming that the strength of naphtha-derived polystyrene is 100, the strength of polystyrene obtained by material recycling is about 90. When the strength of naphtha-derived polystyrene is 100, the strength of recycled polystyrene in the present invention is usually 90 at the lower limit.
, preferably 95 or more, more preferably 97 or more, and still more preferably 99 or more, and although the upper limit is not particularly limited, it is usually 100 or less. Any combination of these upper and lower limits may be used. Assuming that the strength of naphtha-derived polystyrene is 100, the strength of recycled polystyrene may be 100 or more. The strength of polystyrene derived from naphtha is 1
00, the strength of the recycled polystyrene obtained by the present invention is usually greater than 90 and 100 or less, preferably 95 or more and 100 or less, more preferably 97 or more and 100 or less, still more preferably 99 or more and 100 or less.

[Method for measuring polystyrene strength]
The strength of polystyrene can be evaluated by tensile breaking stress according to JIS K 7161-1, 2, or by bending strength according to JIS K 7171, for example. In the case of rubber-modified polystyrene, Charpy impact strength can also be evaluated according to JIS K 7111-1.

The obtained recycled polystyrene exhibits a good hue with a suppressed degree of yellowness when the hue is evaluated by the following measuring method. Specifically, the hue is evaluated by yellowness (YI value) or the like. As the YI value increases toward the plus side, the yellow color becomes stronger, and as the YI value increases toward the minus side, the blue color becomes stronger. The YI value of the recycled polystyrene obtained in the present invention is lower than the YI value of the polystyrene obtained by material recycling, and the difference in the YI values is usually 0.1 or more, preferably 0.3 or more, more preferably 0.5 or more, It is more preferably 1.0 or more. Y.
There is no particular upper limit for the difference in I values.

[Method for measuring polystyrene hue]
The hue of polystyrene can be measured according to JIS K 7373, for example.

<Manufacturing process D of polystyrene products>
A recycled polystyrene product is obtained from recycled polystyrene.
The obtained recycled polystyrene product is, as described above, a good recycled polystyrene product exhibiting strength and hue equivalent to those of naphtha-derived polystyrene.

As for the form of polystyrene products, if they use recycled polystyrene,
There is no particular limitation, and it can be appropriately selected depending on the purpose.
For example, in addition to polystyrene, if necessary, by preparing a composition containing other components such as a coloring agent, water, and an organic solvent, for example, manufacturing polystyrene products used as coating agents, inks, and adhesives can do.
Alternatively, polystyrene products such as stretched sheets and foamed sheets can be produced by molding a composition containing recycled polystyrene into a sheet. Polystyrene products such as food packaging containers (for example, food trays) can also be produced by molding polystyrene sheets.
Furthermore, by injection molding or injection blow molding a composition containing recycled polystyrene, polystyrene products for food containers such as cups and bottles can be produced.

In general, when plastics that have been material-recycled are used for food packaging containers, there are concerns about migration of the contents, and since they cannot be brought into direct contact with food, their applications are limited. However, since the recycled plastic obtained by the present invention is obtained by decomposing, purifying, and polymerizing waste polyplastic into monomers, it can come into direct contact with food, and there is no limitation on its use.

In the above embodiment, the case of using a homopolymer as waste polystyrene has been described, but the present invention is not limited to homopolymers, and can be applied to copolymers, that is, waste styrene copolymers. Such waste styrene copolymers include waste rubber-modified polystyrene (waste HIPS), waste styrene-acrylic copolymer (waste AS resin), waste styrene-butadiene-acrylic copolymer (waste ABS resin), and the like. . Waste polystyrene in the present invention can include these copolymers.

EXAMPLES The present invention will be described in more detail below with reference to Examples, but the scope of the present invention is not limited to these Examples.

(Example 1)
Spent polystyrene products were collected and then ground and pelletized. One ton of pelletized waste polystyrene was put into a thermal decomposition apparatus using microwaves.
The reaction temperature in the thermal decomposition unit is set to 350 ° C., and 2% by mass of waste polystyrene is used as a catalyst.
of silicon carbide was used and the pyrolysis treatment was carried out under a steam purge.
As a result, 600 kg of crude recycled styrene monomer was obtained (60% yield). The purity of the recycled styrene monomer a after purification was slightly less than 95%.

(Example 2)
Crude recycled styrene was prepared in the same manner as in Example 1, except that the monomer oil component excluding the gas flare component was subjected to the thermal cracking unit again before being subjected to the distillation refining step. A monomer was obtained.
As a result, 840 kg of crude recycled styrene monomer was obtained (84% yield). The purity of recycled styrene monomer b after purification was over 99.8%.

(Example 3)
In Example 1, in the second distillation column, the dimer component/other components (α-methylstyrene, etc.) separated from the crude recycled styrene monomer were subjected to the thermal decomposition unit again, except that a step was added. , in the same manner as in Example 1 to obtain a recycled styrene monomer c.
As a result, a further 240 kg of crude recycled styrene monomer was obtained from the dimer component/other components (α-methylstyrene, etc.) separated in Example 1. Combined with the recycled styrene monomer a obtained in Example 1, from Examples 1 and 3, a total of 840
kg of crude recycled styrene monomer was obtained (84% yield). The purity of recycled styrene monomer c after purification was slightly less than 95%.

(Example 4)
Using the recycled styrene monomers a to c obtained in Examples 1 to 3, respectively, a mixed solution consisting of 95 parts of styrene and 5 parts of toluene was prepared. Oxybenzoate was added and fed to a connected tubular reactor at 120-160°C for continuous bulk polymerization. The mixed solution obtained by polymerization was heated to 220° C. with a heat exchanger, volatile components were removed under reduced pressure of 50 mmHg, and then pelletized to obtain recycled polystyrenes A to C.
The strength and hue of each of the recycled polystyrenes A to C obtained were evaluated by the methods described below.

(Comparative example 1)
100 parts by mass of the used styrene-based resin composition was melt-kneaded at a cylinder temperature of 220° C. using a twin-screw kneading extruder, and the strand was cooled with water and then pelletized to obtain polystyrene D.
For polystyrene D obtained by material recycling, by the method described below,
Intensity and hue were evaluated.

As a result of the comparison, it was confirmed that recycled polystyrenes A to C exhibited superior strength and hue compared to polystyrene D obtained by material recycling. The measured strength of polystyrene D obtained by material recycling was 45 MPa, whereas the measured strength of recycled polystyrenes A to C were all 50 MPa. The YI value of polystyrene D obtained by material recycling was 1.0, whereas the value of recycled polystyrenes A to C was 0.4.

[Method for measuring polystyrene strength]
Using the obtained pellets, a dumbbell molded product for evaluation was produced with an injection molding machine (molding temperature: 220°C). Using this dumbbell molded product, a tensile test was performed to measure the tensile breaking stress.

[Method for measuring polystyrene hue]
Using the obtained pellets, a plate molded product for evaluation was produced with an injection molding machine (molding temperature: 220°C). Using this plate molded product, the YI value was measured by the transmission measurement method.

It was found that when recycled styrene monomer is produced from waste polystyrene using the recycling method of the present invention, recycled styrene monomer can be produced with high yield and high purity.
According to the recycling method of the present invention, high-quality styrene monomer can be produced from waste polystyrene, and the recycled polystyrene obtained by polymerizing the recycled styrene monomer was found to be excellent in strength and color.
INDUSTRIAL APPLICABILITY According to the present invention, a 100% recycling-type polystyrene recycling system can be established, which can be expected to recycle 100% of styrene in waste polystyrene products.

1 Waste polystyrene product 2 Recycled styrene monomer 3 Recycled polystyrene 4 Polystyrene product 10 Steam 11 Slurry 12 Clarified slurry 13 Solids (char/inorganic)
14 monomer oil 15 gas flare 16 benzene/toluene/ethylbenzene 17 dimer/others (α-methylstyrene)
A Recovery process B Method for producing recycled styrene monomer C Method for producing recycled polystyrene D Method for producing polystyrene products a Thermal cracking device b Separation device c Condenser d First distillation column e Second distillation column

Claims (6)

A step of thermally decomposing waste polystyrene products including uncolored polystyrene products and colored polystyrene products using a pyrolyzer to obtain recycled styrene monomer from the waste polystyrene;
A step of removing solid matter from the slurry component generated by the thermal decomposition using a separation device, and
A step of thermally decomposing the clarified slurry from which the solids have been removed, using the thermal decomposition apparatus;
A method for recycling waste polystyrene products, comprising: 2. The method for recycling waste polystyrene products according to claim 1 , wherein the waste polystyrene products are pulverized to obtain a pulverized waste polystyrene product, and the pulverized product is thermally decomposed. The step of obtaining the recycled styrene monomer comprises:
a step of thermally decomposing waste polystyrene products using a thermal decomposition apparatus;
By supplying the steam generated by the thermal decomposition to a condenser, the gas flare component is removed from the thermal decomposition product in which the oil component containing the recycled styrene monomer and the gas flare component are mixed, and the oil component containing the recycled styrene monomer is obtained. a step of distilling and refining the oil component containing the recycled styrene monomer using a distillation column to improve the purity of the recycled styrene monomer;
The method for recycling waste polystyrene products according to any one of claims 1 to 3, comprising: 2. The method for recycling waste polystyrene products according to claim 1 , wherein the pyrolyzer is a pyrolyzer using microwaves. The waste polystyrene product according to claim 1 , wherein the recycled styrene monomer contains at least one selected from the group consisting of inorganic substances, aromatic compounds, cyclohexadiene-based compounds, and cyclohexene-based compounds in addition to styrene monomers. Recycling method. A step of collecting waste polystyrene products including uncolored polystyrene products and colored polystyrene products ;
a process of thermally decomposing the collected waste polystyrene products to obtain recycled styrene monomer from the waste polystyrene;
a step of polymerizing the recycled styrene monomer to obtain recycled polystyrene;
A step of removing solid matter from the slurry component generated by the thermal decomposition using a separation device, and
A step of thermally decomposing the clarified slurry from which the solid matter has been removed using the thermal decomposition device, and a step of obtaining a recycled polystyrene product comprising the recycled polystyrene;
A method for recycling waste polystyrene products, comprising:

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