JP2001164035A - Regeneration of expanded polystyrene and impurities- remover used therein - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve problems in the recycle disposition of expanded polystyrene waste, for example, the inefficient transportation of the waste and troublesome removal of impurities, for example, labels stuck to the waste articles. SOLUTION: The impurity removal process is composed of the volume reduction step at which expanded polystyrene waste S is immersed in the solvent 7 to a gel-form solved material S1 in the volume reduction vessel 6, the impurities removal step at which the gel-form solved material S1 is filtered with filters 11 and 12 and a rotary cylindrical filter 24, as gel-form solved material S1 is kept at such a temperature that the material is in the fluid state, to form the gel polystyrene free from impurities S2 and the solvent removal step at which the gel-form polystyrene S2 is heated, as it is kneaded, to evaporate, separate and recover the solvent, while the residual solid polystyrene S3 is formed in the shape and size for easy regeneration.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for regenerating foamed polystyrene, which recycles a foamed polystyrene molded article which becomes waste after being used as a molding material, and an apparatus for removing impurities used in this method. is there.

[0002]

2. Description of the Related Art Expanded polystyrene materials are advantageous in that they are easy to mold, light in weight and have a good cushioning property.
It is widely used as a packing material and container in the distribution stage of the food industry and the electric industry. Once used, these expanded polystyrene molded articles become useless and are often discarded together with garbage. The expanded polystyrene waste is generally transported to an incineration plant or the like and incinerated. However, for the incineration of the expanded polystyrene waste,
Since high heat is generated, the life of the incinerator is shortened, and the environment is polluted by combustion gas and odor. Further, when the waste of expanded polystyrene is discarded in the soil, it is not decomposed, so that there is a problem that it remains as it is and contaminates the soil. In order to solve these problems, reduce the amount of waste generated, prevent global warming, and further utilize resources effectively, a method of collecting and regenerating expanded polystyrene waste has been considered. .

[0003]

However, in recovering and regenerating expanded polystyrene waste,
The following issues remain. (1) In large stores that use a large amount of expanded polystyrene as containers or food trays for various products, a collection basket is installed at the store entrance, etc., when the basket is filled with expanded polystyrene waste. Is transported to a recycling plant. However, it is difficult to secure a space for installing a collection basket for the waste of expanded polystyrene, and the wastes piled up randomly in the collection basket significantly impair the appearance. (2) Also, when transporting expanded polystyrene waste, expanded polystyrene has a large volume in proportion to its weight,
The transportation costs were expensive.

(3) Since the foamed polystyrene waste conveyed to the reprocessing plant has impurities such as gum tape and garbage attached thereto, these impurities are sufficient to regenerate high-quality foamed polystyrene. Need to be removed. However, removing impurities adhering to waste is an extremely laborious and inefficient operation, and there has been no efficient and reliable removal method for even fine impurities.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and makes it easy to collect the waste of expanded polystyrene, reduce the transportation cost to a reprocessing plant, and reduce the amount of impurities adhering to the waste. It is an object of the present invention to provide a method for regenerating expanded polystyrene, which can easily remove polystyrene solids and regenerate a high-quality solid polystyrene, and an apparatus for removing impurities used in the method.

[0006]

In order to achieve the above object, a method for regenerating polystyrene foam according to the present invention comprises immersing used polystyrene foam in a solvent in a volume-reducing container to form a gel-like polystyrene solution. A volume reducing step of reducing the volume, an impurity removing step of heating the gel polystyrene solution, and filtering the gel polystyrene solution with a filter while maintaining a fluid state, and a gel polystyrene solution with impurities removed Is heated while kneading, and the solvent is evaporated and separated, and a solvent separation step of forming the remaining polystyrene into a solid material.

As described above, according to the method for regenerating the expanded polystyrene of the present invention, when the used expanded polystyrene is immersed in the solvent in the reduced volume container, the expanded polystyrene waste is dissolved, and the volume thereof is reduced. As a result, the transportation efficiency to the reprocessing plant can be improved. At the reprocessing plant,
The impurity removal step and the solvent separation step can be performed continuously.In the impurity removal step, the viscosity is reduced by applying a temperature to the gelled polystyrene solution dissolved in the solvent, and the gelated polystyrene solution is removed. Make into a fluid state and filter through a filter. This makes it possible to automatically remove impurities mixed into the gel-like polystyrene without bothering the operator. In the solvent separation step, the gelled polystyrene solution after the impurity removal step is heated while kneading to evaporate and separate the solvent, and the remaining polystyrene is formed into a high-quality solid polystyrene containing no impurities. As described above, the expanded polystyrene regenerating apparatus of the present invention uses expanded polystyrene recovered with high transportation efficiency,
Regeneration processing until a high-quality polystyrene material containing no impurities can be continuously and efficiently performed.

Further, in the impurity removing apparatus used in the method for regenerating expanded polystyrene according to the present invention, which has been made to achieve the above object, the used expanded polystyrene is immersed in a solvent to form a gel-like polystyrene solution. Thereafter, the solvent is evaporated and separated by heating while kneading the gelled polystyrene solution, and the remaining polystyrene is formed into a solid material. It is characterized by comprising a high-temperature storage tank for receiving the gelled polystyrene solution, a filter installed in the high-temperature storage tank, and heating means for maintaining the temperature of the high-temperature storage tank at a predetermined temperature. .

As described above, since the high-temperature heat-holding tank for receiving the gelled polystyrene melt is maintained at a predetermined temperature by the heater, the viscosity of the gelled polystyrene melt dissolved in the solvent can be reduced, and the filter is Impurities can be easily removed.

The impurity removing apparatus used in the method for regenerating expanded polystyrene according to the present invention, which has been made to achieve the above object, comprises immersing used expanded polystyrene in a solvent to form a gel-like polystyrene solution. Thereafter, the solvent is evaporated and separated by heating while kneading the gelled polystyrene solution, and the remaining polystyrene is formed into a solid material. A centrifugal filter having a cylindrical filter for receiving the gel-like polystyrene dissolved material, a cylindrical outer cylinder containing the cylindrical filter, and rotating means for rotating the cylindrical filter; Heating means for maintaining the temperature of the vessel at a predetermined temperature.

As described above, since the centrifugal filter that receives the gelled polystyrene solution is maintained at a predetermined temperature by the heater, the viscosity of the gelled polystyrene solution dissolved in the solvent can be reduced, and the cylindrical filter can be reduced. Thus, impurities can be easily removed.

Further, in the impurity removing apparatus used in the method for regenerating expanded polystyrene according to the present invention which has been made to achieve the above object, the used expanded polystyrene is immersed in a solvent to form a gel-like polystyrene solution. Thereafter, the solvent is evaporated and separated by heating while kneading the gelled polystyrene solution, and the remaining polystyrene is formed into a solid material. A first impurity removing device including a high-temperature heat storage tank that receives the gelled polystyrene solution, a filter installed in the high-temperature heat storage tank, and a heating unit that maintains the temperature of the high-temperature heat storage tank at a predetermined temperature; A cylindrical filter for receiving the gelled polystyrene solution from which impurities have been removed by the first impurity removing device; A centrifugal filter having a cylindrical outer cylinder that houses a cylindrical filter, a rotating unit that rotates the cylindrical filter, and a heating unit that maintains the temperature of the centrifugal filter at a predetermined temperature. And a second impurity removing device.

Thus, the first impurity removing device and the second impurity removing device
Is provided, the impurities can be removed with higher accuracy.

Here, the filters installed in the high-temperature heat storage tank are a primary filter for removing bulky dust and a secondary filter which is finer than the primary filter and is provided downstream of the primary filter. It is desirable. in this way,
Since a primary filter and a secondary filter are provided,
Impurities can be removed more efficiently.

It is desirable that the cylindrical filter of the centrifugal filter be detachably housed inside a reinforcing cylindrical frame having a large number of holes in a peripheral wall. As described above, since the cylindrical filter is detachably accommodated inside the reinforcing cylindrical frame having a large number of holes in the peripheral wall, it is possible to prevent deformation and breakage thereof.

Further, the heating means includes a plurality of heating plates arranged inside the high-temperature storage tank, a hot water heating section provided on the outer wall surface of the high-temperature storage tank and the centrifugal filter,
A hot water tank that heats and holds hot water supplied to the heating plate and the hot water heating unit to a predetermined temperature and stores the hot water, and a feed pump that supplies hot water from the hot water tank to the heating plate and the hot water heating unit. Is desirable. As described above, since the high-temperature heat storage tank and the centrifugal filter are maintained at a predetermined temperature by the heating means, the viscosity of the gelled polystyrene solution dissolved in the solvent can be reduced, and the gelated polystyrene solution can be easily moved. Can be done.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described in the order of processing steps with reference to the drawings. 1 is an explanatory view showing an outline of an apparatus for regenerating expanded polystyrene, FIG. 2 is an explanatory view of a regenerating method, FIG. 3 is a partially cutaway perspective view for explaining the structure of a high-temperature heat storage tank, and FIG. FIG. 5 is an exploded perspective view showing a main part of the centrifugal filter, and FIG. 5 is a perspective view showing an internal structure of the volume reduction device.

The volume reducing device A shown in FIG. 1 is a device for dissolving expanded polystyrene waste S in a solvent 7 to reduce its volume. The volume reducing device A will be described in detail with reference to FIG. 5. A handle 3 provided on the upper portion of the casing 1 and manually operated from the outside, a pressing rod 4 that moves up and down by rotating the handle 3, A pressing mechanism 2 including a pressing plate 5 provided at a lower end is provided. A volume reduction container 6 is disposed directly below the pressing plate 5. Further, the volume reducing container 6 contains a solvent 7 for dissolving the expanded polystyrene.

The solvent 7 is an ester compound solvent containing an ester synthetic oil as a main component, has no teratogenicity or carcinogenicity, has excellent biodegradability, has a high flash point of 100 ° C., and has a high degree of deterioration of polystyrene. Can be minimized. An opening 8 that can be opened and closed is provided on the side wall of the casing 1.

The expanded polystyrene waste S supplied from the input port 8 of the volume reducing device A thus configured is dropped into the volume reducing container 6, and the solvent is moved by the pressing plate 5 which is lowered by operating the handle 3. 7 dipped. As a result, the waste of the expanded polystyrene is dissolved to form a gel polystyrene dissolved material S ₁ (see FIG. 2) whose volume is reduced by compression. In addition, since the volume reduction container 6 is accommodated in the casing 1 fixed to the installation location, there is no possibility that a person touches the solvent 7 or the volume reduction container 6 falls down and the solvent 7 flows out. It is safe to install in places with many people.

With the volume reducing device A configured as described above, the foamed polystyrene waste S can be dissolved in the solvent 7 and its volume can be made extremely small. Moreover, since a large amount of expanded polystyrene waste is stored in the volume reduction container 6 as a gel-state polystyrene melt S ₁ compressed volume reduction,
If a large number of volume-reducing containers 6 are loaded on a transportation means T such as a truck and transported to a recycling factory (see FIG. 1), the transportation cost of the expanded polystyrene waste S can be reduced.

Further, even if impurities such as labels and gum tapes adhere to the expanded polystyrene waste S, it is not necessary to remove the impurities, and it can be directly introduced into the solvent 7.
At this time, the foamed polystyrene waste S is dissolved in the solvent 7, but remains as impurities such as the label and the gum tape.

Next, description will be made regarding the playback processing of the gel-state polystyrene melt S ₁ carried by the transport means T such as a truck. The gel-state polystyrene lysate reproduction processing apparatus to S ₁ to play process is composed of and a solvent separation apparatus C impurity removal device B, and he placed generally regeneration treatment plant. The impurity removing device B includes a first impurity removing device including a high-temperature heat storage tank 9 and a centrifugal filter 1.
4 and a second impurity removing device.

As shown in FIG. 3, the first impurity removing device is installed on the high-temperature heat storage tank 9 and on the upper surface of the high-temperature heat storage tank 9 (in FIG. 1, for easy understanding, the high-temperature heat storage tank 9 is used). 9 (shown above 9) and a secondary filter 12 installed at the lower part of the high-temperature heat storage tank 9 with a fine mesh. The hot Honetsuso 9, a gel-state polystyrene lysate S ₁ temporarily stored, as described below, heating the gel-state polystyrene lysate S ₁ to a predetermined temperature, and held,
Its viscosity is reduced and fluidity is improved.

The primary filter 11 is formed coarsely in order to remove a large dust such as a label and a gum tape adhered to the foamed polystyrene waste S.
To remove coarse dirt, such as duct tape, whereas the gel-state polystyrene lysate S ₁ can be passed through. In addition, 2
The secondary filter 12 has finer eyes than the primary filter 11 and removes dust that could not be removed by the primary filter 11.

Further, the high-temperature heat storage tank 9 accommodates a plurality of heating plates 31 each having a hot water channel provided therein, and a hot water heating section 32 formed of a hot water channel on its outer wall surface. . The plurality of heating plates 31 are connected pipes 31.
The hot water, which is connected by a and is heated and maintained at a predetermined temperature, flows through each heating plate 31.
The hot water flowing through the heating plate 31 is supplied to a hot water heating unit 3 comprising a hot water channel provided on an outer wall surface of the high-temperature heat storage tank 9.
2.

In the vicinity of the first impurity removing device, there is provided a container lifter 10 for supplying the gelled polystyrene dissolved material S ₁ stored in the volume reducing container 6 to the high-temperature heat retaining tank 9. The container lifter 10 supplies the gelled polystyrene solution S ₁ in the volume reduction container 6 into the high-temperature heat storage tank 9. The container lifter 10 fixes the volume reduction container 6 on a vertically movable platform 16 and raises the container. The lifting platform 16 is configured to tilt at the rising end. As a result, the volume-reducing container 6 is tilted to the angle indicated by the chain line in FIG. 1, and the gelled polystyrene dissolved material S ₁ in the volume-reducing container 6 is supplied to the upper surface of the high-temperature heat storage tank 9. At this time, the primary filter 11, the heating plate 31, by the heat from hot water heating unit 32, because it is heated, also gel-state polystyrene melt S ₁ is being turned in a highly viscous state, by the heat, Viscosity can be reduced.

Thereafter, the gelled polystyrene solution S
₁ is dropped and supplied into the high-temperature storage tank 9 through the primary filter 11. The gel-like polystyrene solution S ₁ in the high-temperature storage tank 9 is made to have a lower viscosity by the heat from the heating plate 31 and the hot water heating unit 32. Then, after passing through a fine-grained secondary filter 12 provided near the bottom of the high-temperature heat storage tank 9, a feed pump 17 passes through a pipe 13 to a second impurity removing device including a centrifugal filter 14. Sent.

Next, a second impurity removing device including the centrifugal filter 14 will be described. The second impurity removing device includes:
As shown in FIGS. 1 and 4, a cylindrical filter 24 for receiving a gel-like polystyrene solution from which impurities have been removed by the first impurity removing device, and a cylindrical outer tube for housing the cylindrical filter 24 Centrifugal filter 1 having a rotating means 18 for rotating the cylindrical filter 14
4 and heating means for maintaining the temperature of the centrifugal filter 14 at a predetermined temperature.

The centrifugal filter 14 is provided with the hot water jacket 1.
The peripheral wall lower end of the outer tube 18 having a 8a, delivery pipe 19 for feeding the gel-state polystyrene melt S ₂ which is removal of impurities
Is provided, and a delivery pump 20 is provided in the delivery pipe 19. A rotation shaft 21 is rotatably fitted to the bottom wall of the outer cylinder 18, and the bottom wall of the reinforcing cylinder frame 22 is fixed to the upper end of the rotation shaft 21. The upper part of the reinforcing tubular frame 22 is open,
A number of holes 23 are provided in the peripheral wall.

An extremely fine cylindrical filter 24 having an open upper portion is configured to be housed inside the reinforcing cylindrical frame 22, and is configured to be removable as required. A pulley provided at the lower end of the rotary shaft 21, a pulley provided at the output shaft end of the motor 25, and a belt 26 wound around both pulleys are provided as rotating means for rotating the cylindrical filter 14. When the motor 24 is started, the tubular filter 24 rotates integrally with the reinforcing tubular frame 22. The cylindrical filter 24 has finer eyes than the secondary filter 12 and removes extremely small dust that cannot be removed by the secondary filter 11.

A hot water jacket 18a is provided on the outer wall surface of the outer cylinder 18 of the centrifugal
It is possible to maintain the gel-state polystyrene melt S ₂ that is inside the predetermined temperature. The hot water flowing through the hot water jacket 18 a is supplied to each heating plate 31, a first hot water heating section 32 provided in the high-temperature holding tank 9, and a first hot water provided in the pipe 13.
What flows through the hot water heating unit 33 is used. The hot water flowing through the hot water jacket 18 a flows through a third hot water heating unit 34 provided in the delivery pipe 19 and is used to warm the delivery pipe 19.

As described above, since the gel-like polystyrene solution S ₂ inside the centrifugal filter 14 can be maintained at a predetermined temperature, the viscosity can be prevented from increasing. As a result, the gel-like polystyrene solution S ₂ can easily pass through the cylindrical filter 24, and the gel-like polystyrene solution S ₂ can be smoothly sent out from the delivery pipe 19.

Each heating plate 31, first hot water heating unit 3
2, the second hot water heating unit 33, the hot water jacket 18a, the third
The heater 15 that heats hot water flowing through the hot water heating unit 34 will be described. The heater 15 is a heater 27 with a thermo.
A hot water tank 28 for storing hot water kept at a predetermined temperature by a heater 27 with a thermostat, a discharge pipe 30 for sending hot water from a hot water tank 28 by a feed pump 29, and a return pipe 35.

That is, the hot water kept at a predetermined temperature flows from the discharge pipe 30 to the hot water flow path of the heating plate 31, and flows to another heating plate 31 by the connecting pipe 31a. Thereafter, the hot water passes through the first hot water heating unit 32, the second hot water heating unit 33 connected to the first hot water heating unit 32, the hot water jacket 18 a of the centrifugal filter 14, the third hot water heating unit 34, and the return pipe 35. After returning to the tank 28 and being heated again, it is sent out.

Next, the solvent separating / separating apparatus C for separating the solvent from the gelled polystyrene solution S ₂ from which impurities have been removed will be described. A screw type kneading heater (not shown) is provided inside the casing 36 of the solvent separating / separating apparatus C for evaporating and separating the solvent while kneading the gelled polystyrene solution S ₂ from which impurities have been removed. The collected solvent is suctioned to the outside of the casing 36 by a negative pressure and collected, and a solvent recovery means 37 for cooling and liquefying, a solvent recovery tank 38 for storing the recovered liquefied solvent, and a discharge side of the screw type kneading heater are provided. And a molding machine (not shown) for molding the polystyrene S ₃ from which the solvent has been separated and solidified into pellets having an appropriate shape and dimensions and discharging the pellets from the end of the casing 36.

Next, a series of the reproduction processing of the gel-state polystyrene melt S ₁ which is dissolved in a solvent 7, FIG. 1, FIG. 2
It will be described based on. First, the feed pump 2 of the heater 15
9, the hot water heated to 80 ° C. to 90 ° C. is supplied to the hot water flow path in the heating plate 31, the first hot water heating unit 32, and the second hot water heating unit 32.
After passing through the hot water heating section 33, the hot water jacket 18a, and the third hot water heating section 34, the heating plate 31, the high temperature heat storage tank 9, the pipe 13, the centrifugal filter 14, and the delivery pipe 19 are heated and kept warm. Then, the reduced-volume container 6 containing the gelled polystyrene solution S ₁ is placed on and fixed to the container lifter 10, then raised, and tilted at the rising end, so that the internal gelled polystyrene solution S ₁ is placed on the filter 11. After dropping and removing the bulky waste, it is stored in the high-temperature heat storage tank 9.

The gelled polystyrene solution S ₁ accommodated in the high-temperature storage tank 9 is brought down to a predetermined temperature while flowing downward while contacting the plurality of heating plates 31 and the inner wall surface of the high-temperature storage tank 9. Heated and held. As a result, decreases the viscosity of the gel-state polystyrene lysate S _1, the fluidity is improved. Then, when passing through the second filter 12, impurities are further removed, pass through the pipe 13, and pass through the centrifugal filter 1.
4 to the cylindrical filter 24.

The centrifugal filter 14 filters the gelled polystyrene solution S ₁ by centrifugal force by rotating the cylindrical filter 24. At this time, although the cylindrical filter 24 is a very fine mesh, it has a high fluid passage resistance. However, the gel-like polystyrene dissolved matter S ₁ is maintained at a high temperature and is subjected to centrifugal force. It passes smoothly, becomes a gel-like polystyrene solution S ₂ from which ultrafine impurities have been removed, and is sent to the solvent separation device C via the delivery pipe 19.

The solvent separating device C is automatically operated continuously in synchronization with the impurity removing device B, and the gel-free polystyrene dissolved material S from which the impurity is removed is sent out from the impurity removing device B.
₂ is separated into solidified polystyrene S ₃ and solvent 7.
The solidified polystyrene S ₃ is reused as a raw material for expanded polystyrene, and the separated solvent 7 is reused as a solvent for reducing the volume of expanded polystyrene.

In the above embodiment, the same hot water is used as the hot water flowing through each of the heating plates 31, the first hot water heating section 32, the second hot water heating section 33, the hot water jacket 18a, and the third hot water heating section 34. However, the present invention is not particularly limited to this, and piping may be separately provided for each heating means. In the above embodiment, hot water is used, but an electric heater may be used. Further, each of the heating plate 31, the first hot water heating unit 32, and the hot water jacket 18a is a so-called combined type using hot water, and the second hot water heating unit 33 and the third hot water heating unit 34 using electric heaters. There may be.

[0042]

Since the present invention is constructed as described above, it is possible to easily recover the waste of expanded polystyrene, to reduce the transportation cost to the reprocessing plant, and to reduce the amount of impurities adhering to the waste. Can be easily removed, and a high-quality solid polystyrene can be regenerated.

[Brief description of the drawings]

FIG. 1 is an explanatory view showing an outline of an entire apparatus for regenerating a polystyrene foam.

FIG. 2 is an explanatory diagram of a reproduction processing method.

FIG. 3 is a partially cutaway perspective view illustrating the structure of a high-temperature heat storage tank.

FIG. 4 is an exploded perspective view showing a main part of the centrifugal filter.

FIG. 5 is a perspective view showing the internal structure of the volume reduction device.

[Explanation of symbols]

S Waste of polystyrene foam S ₁ Melt of polystyrene gel S ₂ Melt of polystyrene from which impurities have been removed S ₃ Solidified polystyrene A Volume reducer B Impurity remover C Solvent separator 2 Press mechanism 5 Press plate 6 Volume reducer 7 Solvent 9 High-temperature heat storage tank 11 Primary filter 12 Secondary filter 13 Pipe 14 Centrifugal filter 15 Heater 17 Feed pump 18a Hot water jacket 22 Reinforcement cylinder frame 23 Hole 25 Motor 28 Hot water tank 29 Feed pump 31 Heating plate 32 1 hot water heating section 33 second hot water heating section 34 third hot water heating section 36 casing 38 solvent recovery tank

Claims (7)

[Claims] 1. A volume reduction step of immersing used expanded polystyrene in a solvent in a volume reduction container to reduce the volume to a gelled polystyrene solution, and heating the gelled polystyrene solution.
An impurity removing step of filtering the gel-like polystyrene solution with a filter while maintaining a fluid state, and heating and kneading the gel-like polystyrene solution from which the impurities have been removed to evaporate the solvent and separate the remaining polystyrene into a solid. A method for regenerating polystyrene foam, comprising: a solvent separation step of forming a polystyrene foam. 2. Spent foamed polystyrene is immersed in a solvent to form a gel-like polystyrene solution, and the mixture is heated while kneading the gel-like polystyrene solution to evaporate and separate the solvent. An impurity removal apparatus used in a method for regenerating expanded polystyrene to be molded into a foamed polystyrene, wherein the impurity removal apparatus includes: a high-temperature heat storage tank that receives the gelled polystyrene solution; a filter installed in the high-temperature heat storage tank; And a heating means for maintaining the temperature of the heat retaining tank at a predetermined temperature. 3. Spent foamed polystyrene is immersed in a solvent to form a gel-like polystyrene solution, and then heated while kneading the gel-like polystyrene solution to evaporate and separate the solvent. An impurity removing device used in a method for regenerating expanded polystyrene to be formed into a tubular filter, wherein the impurity removing device has a cylindrical filter that receives the gel-like polystyrene dissolved material, and a cylindrical outer cylinder that houses the cylindrical filter. And a centrifugal filter having rotating means for rotating the cylindrical filter; and a heating means for maintaining the temperature of the centrifugal filter at a predetermined temperature. Impurity removal equipment used for 4. Spent foamed polystyrene is immersed in a solvent to form a gel-like polystyrene solution, and the mixture is heated while kneading the gel-like polystyrene solution to evaporate and separate the solvent. An impurity removal apparatus used in a method for regenerating expanded polystyrene to be molded into a foamed polystyrene, wherein the impurity removal apparatus includes: a high-temperature heat storage tank that receives the gelled polystyrene solution; a filter installed in the high-temperature heat storage tank; A first impurity removing device comprising heating means for maintaining the temperature of the heat retaining tank at a predetermined temperature; and a cylindrical filter for receiving the gelled polystyrene dissolved matter from which the impurities have been removed by the first impurity removing device; A cylindrical outer cylinder that houses the cylindrical filter,
A foaming apparatus comprising: a centrifugal filter having rotating means for rotating the cylindrical filter; and a second impurity removing device comprising heating means for maintaining the temperature of the centrifugal filter at a predetermined temperature. Impurity removal device used in polystyrene regeneration treatment method. 5. A filter installed in the high-temperature heat storage tank is a primary filter for removing bulky dust and a secondary filter provided finer than the primary filter and provided downstream of the primary filter. The impurity removing apparatus used in the method for regenerating expanded polystyrene according to claim 2 or 4. 6. The filter according to claim 3, wherein the cylindrical filter of the centrifugal filter is detachably housed inside a reinforcing cylindrical frame having a large number of holes in a peripheral wall. For removing impurities used in a method for regenerating expanded polystyrene. 7. The heating means comprises: a plurality of heating plates arranged inside the high-temperature storage tank; a hot-water heating section provided on the outer wall surface of the high-temperature storage tank and a centrifugal filter; It is characterized by comprising a hot water tank for heating and holding hot water supplied to the plate and the hot water heating unit to a predetermined temperature and storing the hot water, and a feed pump for supplying hot water from the hot water tank to the heating plate and the hot water heating unit. An impurity removing apparatus used in the method for regenerating expanded polystyrene according to claim 4.