KR20200083811A - Polysthylene extraction system for recycling of fire resilient styroform - Google Patents

Abstract

The present invention relates to a polystyrene extraction system for recycling fire retardant styroform, which can separate and extract a flame retarding material and polystyrene from fire retardant styroform so as to extract high purity polystyrene, and helps recycle the fire retardant styroform so as to prevent environmental pollution and create a new profit. For this purpose, the polystyrene extraction system comprises: at least one dissolving tank which generates a dissolving solution by stirring the raw material produced by the pulverization of the reduced fire retardant styrofoam and a solvent for dissolving the raw material at a preset mixing ratio; a filtering unit for extracting a filtering solution in which the solvent from the dissolving solution and the polystyrene contained in the raw material are mixed together; a filtering solution storage tank in which the filtering solution is stored; and a filtering solution separation unit which separates the filtering solution into solvent and polystyrene.

Description

Polystyrene extraction system for recycling of flame retardant styrofoam {POLYSTHYLENE EXTRACTION SYSTEM FOR RECYCLING OF FIRE RESILIENT STYROFORM}

The present invention relates to a polystyrene extraction system for recycling of flame-retardant styrofoam, more specifically, it is possible to extract high-purity polystyrene by separating and extracting flame retardant and polystyrene from flame-retardant styrofoam, and helping to recycle flame-retardant styrofoam to prevent environmental pollution and recycling. It relates to a polystyrene extraction system for recycling of flame-retardant styrofoam that can promote the creation of new revenue in the market.

In general, expanded polystyrene, better known under the trade name Styrofoam, is lightweight and has excellent impact absorption and heat retention, making it widely used as packaging containers for various products, thermal insulation materials, and buoyancy balls. Since these styrofoam products are relatively weak in durability and inexpensive, most of them are discarded after being used once, so a huge amount of styrofoam is generated every day nationwide.

Waste styrofoam is incinerated and disposed of mainly because it does not rot well in its natural state. In this process, harmful gases that cause environmental pollution such as dioxins, which are known as carcinogens, are generated. Therefore, efforts to increase the recycling rate of the waste styrofoam have been attempted in various ways, but the waste styrofoam is very bulky and has a difficulty in collecting and transporting it. In accordance with these social demands, volume reduction techniques have been developed to reduce the volume of waste styrofoam and improve recycling efficiency.

More than 95% of white styrofoam that is distributed in Korea is collected and recycled, and collected by the collectors and classified into A, B, and C grades and sold to pellet processing companies. As it is being distributed in a manner, recycling equipment such as reducers, extruders, and injection machines are also growing together, and the technology is progressing considerably.

However, in the case of sandwich panels used in buildings according to the building law revised since 1995, flame retardant styrofoam should be used. When producing flame retardant styrofoam, flame retardant and expanded graphite are added to polystyrene beads. When these flame retardants are molded, they cause defects such as bubbles and depressions. For over 20 years, flame retardant styrofoam has been neglected in the recycling market.

However, recently, the demand for flame retardant styrofoam is rapidly increasing nationwide, thanks to the process of rebuilding and the expansion of new industrial complexes, etc., due to the arrival of the endurance of buildings. Therefore, it has become a major cause of national neglect and environmental pollution.

Republic of Korea Patent Publication No. 2017-0035203 (Name of invention: recycled resin production device and recycled resin production method, published on March 30, 2017)

The purpose of the present invention is to solve the conventional problems, by separating and extracting the flame retardant and polystyrene from the flame retardant styrofoam can extract the high purity polystyrene, help the recycling of the flame retardant styrofoam to prevent environmental pollution and create new revenue in the recycling market The present invention is to provide a polystyrene extraction system for recycling of flame retardant styrofoam that can be promoted.

According to a preferred embodiment for achieving the object of the present invention described above, the polystyrene extraction system according to the present invention is stirred by a predetermined mixing ratio of the raw material generated by the grinding of the reduced flame retardant styrofoam and the solvent for dissolving the raw material One or more dissolving baths that produce a dissolving solution; A filtering unit extracting a filtering solution in which the solvent and the polystyrene contained in the raw material are mixed from the solution; A filtering liquid storage tank in which the filtering liquid is stored; And a filtering liquid separation unit separating the filtering liquid into the solvent and the polystyrene.

The polystyrene extraction system according to the present invention includes a raw material hopper in which the raw material is stored; A solvent storage tank in which the solvent is stored; And a weighing unit that supplies the raw material and the solvent at a preset mixing ratio. It further includes at least one of.

Here, in the filtering unit, the filtering solution is extracted as the lysate passes through a multi-stage filtering means and is filtered over a predetermined filtration purity.

Here, the filtering means extracts the filtering solution using any one of a bag filter method, a shake method, and a centrifugal separation method.

Here, the filtering unit, a multi-stage bag filter unit for passing the filtering solution from the lysate by a bag filter; And a filtration unit that filters the filtering liquid that has passed through the bag filter unit to a predetermined filtration purity or higher.

Here, the filtering unit, shaker unit for passing the filtering solution in the lysed by the shaker stacked apart from each other in multiple stages; And a filtration unit that filters the filtering solution that has passed through the shaker unit to a predetermined filtration purity or higher.

Here, the filtering unit, a first centrifuge for centrifuging the lysate to extract a one-dimensional centrifuge; A second centrifugal separator for centrifuging the one-dimensional centrifugation liquid to extract the two-dimensional centrifugation liquid; A third centrifuge for centrifuging the two-dimensional centrifugation solution to extract the filtering solution; And a filtration unit that filters the filtering solution that has passed through the third centrifuge to a predetermined filtration purity or higher.

Here, the filtering unit is provided with a flotation separation tank that floats and extracts fine sludge from the filtering liquid using a microbubble.

Here, the polystyrene in the filtering liquid separation unit is extracted in a solid state by heating the filtering liquid supplied through the filtering liquid storage tank directly or indirectly at a preset temperature range, and the solvent in the filtering liquid separation unit. Is extracted in a gaseous state according to the vaporization of the filtering liquid by heating.

Here, the filtering liquid separation unit, a liquid storage tank in which the filtering liquid supplied from the filtering liquid storage tank is accommodated; And a heating unit that heats at least one of the liquid storage tank and the filtering liquid so that the inside of the liquid storage tank maintains a predetermined temperature range.

Here, the filtering liquid separation unit, while rotating the filtering liquid supplied from the filtering liquid storage tank at least one screw unit for heating the inside to maintain a predetermined temperature range; includes, but, the screw unit, the filtering liquid A screw barrel through which the filtering liquid supplied from the storage tank passes; A barrel screw rotatably coupled to the screw barrel to rotate and move the filtering solution; A barrel reducer for rotating the barrel screw at a predetermined reduction ratio; And a barrel heater provided on an outer circumferential surface of the screw barrel to dissipate heat so that the inside of the screw barrel maintains a predetermined temperature range.

Here, the filtering liquid separation unit, the input screw unit for rotating the filtering liquid supplied from the filtering liquid storage tank; A discharge screw unit that rotates and moves the filtering liquid delivered from the input screw unit; A hot water storage tank in which the input screw unit and the discharge screw unit are immersed so that hot water is accommodated so that the inside maintains a predetermined temperature range; And a mixing net mounted on at least one of the input screw unit and the discharge screw unit so that the hot water and the filtering liquid contact directly or indirectly.

Here, the filtering liquid separation unit, a hot water storage tank in which hot water is accommodated so that the inside is maintained within a predetermined temperature range; A liquid spray unit for spraying the filtering liquid stored in the filtering liquid storage tank to the hot water storage tank or the hot water surface; And according to the vaporization of the filtering liquid, the carrying unit for discharging the floating matter floating in the hot water of the hot water storage tank to the outside of the hot water storage tank.

Here, the filtering liquid separation unit, the hot water injection unit for spraying the hot water having a predetermined temperature range on at least one of the filtering liquid and the hot water surface inside the hot water storage tank; A hot water circulation unit for moving the floating material floating on the hot water surface toward the carrying unit; And a dewatering unit that dehydrates the polystyrene carried out by the carrying unit. It further includes at least one of.

Here, the filtering liquid separation unit, a hot air reaction tank; A liquid spray unit for spraying the filtering liquid into the hot air reaction tank; A hot air injection unit for spraying hot air having a predetermined temperature range in the hot air reaction tank or in the filtering liquid; And a powder blower for discharging polystyrene generated in the hot air reaction tank according to the vaporization of the filtering liquid by hot air.

Here, the filtering liquid separation unit, cyclone to extract the solvent in the gaseous state by applying a centrifugal force to the polystyrene delivered from the powder blower; And a powder container for reducing the polystyrene delivered from the powder blower. It further includes at least one of.

Here, the filtering solution separation unit, mixing the filtering solution and the anti-solvent contained in the filtering solution storage tank to produce an anti-solvent mixture and an anti-solvent extraction tank for extracting the polystyrene from the anti-solvent mixture; And a fractional distiller which fractionally distills the remaining anti-solvent mixture after the polystyrene has been extracted into the anti-solvent and the solvent by boiling point difference.

Here, the filtering liquid separation unit, a heat exchange unit for liquefying the solvent in the gas phase; is provided.

According to the polystyrene extraction system for recycling of flame retardant styrofoam according to the present invention, high-purity polystyrene can be extracted by separating and extracting flame retardant and polystyrene from flame retardant styrofoam, and helping recycling of flame retardant styrofoam to prevent environmental pollution and new profits in the recycling market We can promote creation.

In addition, the present invention can stably form a flame-retardant styrofoam through an incoat through reduction of a flame-retardant styrofoam.

In addition, the present invention can stabilize the stirring of the raw material and the solvent in the dissolution tank through the dissolution stirring unit.

In addition, the present invention can accurately mix the raw material and the solvent through the limitation of the weighing unit and the preset mixing ratio, and make it possible to make clear the combination of the solvent and the polystyrene.

In addition, the present invention can stably extract the filtering solution from the lysing solution through the filtering unit, and improve the purity of the filtering solution to 95% or more.

In addition, the present invention can stabilize the extraction and discharge of sludge from the melt through the filtering unit.

In addition, the present invention can stabilize the separation of the filtering solution and the sludge from the solution through centrifugation of the solution.

In addition, the present invention can stably float fine sludge from the filtering liquid through the floating separation tank to further improve the purity of the filtering liquid, and the generation of microbubbles in the filtering liquid as an organic solvent through a radical (not shown). Can promote.

In addition, the present invention can extract solid polystyrene in high purity from the filtering liquid through the filtering liquid separation unit, and can separate and extract the gaseous solvent from the filtering liquid.

In addition, the present invention can promote the vaporization of the solvent in the filtering solution using direct or indirect heating of the filtering solution in the filtering solution separation unit.

In addition, the present invention can separate the hot water mixed for heating the filtering liquid in the filtering liquid separation unit, it is possible to stably extract the polystyrene mixed in the hot water.

In addition, the present invention can simplify the extraction of polystyrene from the filtering solution through mixing of the filtering solution and the anti-solvent in the filtering solution separation unit.

In addition, the present invention can be separated and extracted with an anti-solvent and a solvent using a difference in boiling point according to the fractional distillation of the polystyrene-removed anti-solvent mixture.

In addition, the present invention can be liquefied stably by separately storing the vaporized anti-solvent and the vaporized solvent, and recycle the liquefied anti-solvent and the liquefied solvent.

In addition, the present invention can prevent the mixing of the polystyrene and moisture extracted from the filtering liquid according to heating of the filtering liquid by the hot air in the filtering liquid separation unit, and increase the purity of the extracted polystyrene to obtain stable polystyrene.

1 is a block diagram showing a polystyrene extraction system according to an embodiment of the present invention.
2 is a block diagram showing a first example of a filtering unit in a polystyrene extraction system according to an embodiment of the present invention.
3 is a block diagram showing a second example of the filtering unit in the polystyrene extraction system according to an embodiment of the present invention.
4 is a block diagram showing a third example of the filtering unit in the polystyrene extraction system according to an embodiment of the present invention.
5 is a block diagram showing a first example of a filtering liquid separation unit in a polystyrene extraction system according to an embodiment of the present invention.
6 is a block diagram showing a modification of the first example of the filtering liquid separation unit in the polystyrene extraction system according to an embodiment of the present invention.
7 is a block diagram showing a second example of the filtering liquid separation unit in the polystyrene extraction system according to an embodiment of the present invention.
8 is a block diagram showing a third example of the filtering liquid separation unit in the polystyrene extraction system according to an embodiment of the present invention.
9 is a block diagram showing a fourth example of the filtering liquid separation unit in the polystyrene extraction system according to an embodiment of the present invention.
10 is a block diagram showing a modification of the fourth example of the filtering liquid separation unit in the polystyrene extraction system according to an embodiment of the present invention.
11 is a block diagram showing a fifth example of the filtering liquid separation unit in the polystyrene extraction system according to an embodiment of the present invention.
12 is a block diagram showing a sixth example of the filtering liquid separation unit in the polystyrene extraction system according to an embodiment of the present invention.

Hereinafter, an embodiment of a polystyrene extraction system for recycling of flame retardant styrofoam according to the present invention will be described with reference to the accompanying drawings. At this time, the present invention is not limited or limited by the examples. In addition, in describing the present invention, detailed descriptions of known functions or configurations may be omitted to clarify the gist of the present invention.

1 to 11, the polystyrene extraction system according to an embodiment of the present invention can extract and recycle polystyrene (PS) from a flame retardant styrofoam.

Here, the flame retardant styrofoam represents a state in which a flame retardant (expanded graphite + flame retardant) and polystyrene (PS) are bound.

In addition, the raw materials are produced in powder form according to the grinding of the reduced flame retardant styrofoam.

In addition, the solvent is not ignited as a catalyst stock solution for dissolving the flame retardant styrofoam, has a low vaporization point, is not fatal to the human body, and has a very small reaction force with synthetic resins other than polystyrene (PS). The solvent (MC) may be made of any one of benzene, thinner, gasoline, acetone, and methylene chloride. In particular, the solvent (MC) may be made of methylene chloride. Methylene chloride, a solvent (MC), does not ignite, has a vaporization point of between 35 degrees Celsius and 45 degrees Celsius, and is not fatal to the human body unless directly inhaled, so it is relatively actively used in semiconductor manufacturing and washing. In addition, methylene chloride as a solvent (MC) is excellent for dissolving polystyrene, but does not react with polypropylene (PP, Polypropylene) or polyethylene (PE, Polyethylene).

Further, the dissolved solution is a mixed solution in which a solvent (MC) is mixed with a raw material in powder form.

In addition, the filtering solution is a liquid in which polystyrene (PS) is dissolved in methylene chloride, which is a solvent (MC), and is extracted through the filtering unit 40.

In addition, the anti-solvent (G) is a liquid for extracting polystyrene (PS) from the filtering solution, and can react with the solvent (MC) methylene chloride of the filtering solution to separate polystyrene (PS) from methylene chloride. Antisolvents (G) include alcohols. In particular, the anti-solvent (G) may be made of methanol. Methanol, the anti-solvent (G), shows the most excellent results compared to other alcohols in the same amount in the shape experiment in which polystyrene (PS) is separated from the filtering liquid and in the saturation experiment with the filtering liquid.

The storage tanks, tanks, and barrels described below may be prevented from spreading into the atmosphere by preventing the solvent MC from spreading to the atmosphere.

The polystyrene extraction system according to an embodiment of the present invention includes one or more dissolving tanks (30) for stirring a raw material and a solvent (MC) for dissolving the raw materials produced by crushing the reduced flame retardant styrofoam at a predetermined mixing ratio (30). ), a filtering unit 40 for extracting a filtering solution containing a mixture of a solvent (MC) and polystyrene (PS) contained in the raw material from the solution, a filtering solution storage tank 50 in which the filtering solution is stored, and a filtering solution. It includes a filtering solution separation unit 60 to separate the solvent (MC) and polystyrene (PS). In one embodiment of the present invention, three dissolution tanks 30 may be provided. Here, the dissolution tank 30 is provided with a dissolution stirring unit 31 for stirring the accommodated raw material and the solvent (MC) to stabilize the mixing of the raw material and the solvent (MC) in the solution, polystyrene (PS) in the solvent (MC) Let it dissolve stably.

The polystyrene extraction system according to an embodiment of the present invention includes a raw material storage tank in which raw materials are stored, a solvent storage tank 20 in which solvents (MC) are stored, and a weighing unit for supplying raw materials and solvents (MC) at a predetermined mixing ratio. It may further include at least one.

The raw material storage tank includes a raw material hopper 10 in which raw materials in powder form are stored, and further includes an incoat grinder 11 for crushing the incoat produced according to the reduction of the flame retardant styrofoam, and the incoat by reducing the flame retardant styrofoam. It may further include an incoat maker 12 for producing.

The metering unit corresponds to a first mixing amount (C1) for supplying raw materials to the dissolving tank (30) in a first input amount corresponding to a preset mixing ratio, and a solvent (MC) to a dissolving tank (30) in a second input amount in response to a preset mixing ratio. It may include a second meter (C2) to supply, and a metering controller (PLC) for controlling the first input amount and the second input amount at a predetermined mixing ratio.

In the weighing unit, the weighing controller (PLC) sets the second input amount of the solvent MC to 390 parts by weight to 410 parts by weight with respect to 100 parts by weight of the first input amount of the raw material so that the preset mixing ratio is set to 1.0:3.9 to 1.0:4.1. Can. In the metering unit of one embodiment of the present invention, the metering controller (PLC) may set the second input amount of the solvent MC to 400 parts by weight with respect to 100 parts by weight of the first input amount of the raw material so that the preset mixing ratio is set to 1.0:4.0.

In the filtering unit 40, the filtering solution is extracted as the lysate passes through a multi-stage filtering means and then is filtered over a predetermined filtration purity. In another expression, in the filtering unit 40, as the lysate passes through the multi-stage filtering means, the sludge containing the flame retardant is separated from the lysate to extract the filtering solution first, and the first extracted filtering solution extracts the filtration unit. It is filtered over a predetermined filtration purity. At this time, the filtering unit 40 may be provided with a floating separation tank 47 for extracting the fine sludge contained in the filtering liquid to be passed through the filtering unit or the primary extraction. The floating separation tank 47 can be obtained by floating fine sludge from the filtering liquid using a microbubble, thereby obtaining a high-purity filtering liquid.

Here, the filtering means can be largely classified into a bag filter method, a shaker method, and a centrifugal separation method.

The bag filter method may be represented as a first example of the filtering unit 40 as shown in FIG. 2. The filtering unit 40 according to the first example is a multi-stage bag filter unit 41 for passing the filtering solution from the lysate by the bag filter 411, and the filtering solution passing through the bag filter unit 41 is preset. It may include a filtration unit to filter the filtration purity or more. Then, the filtering liquid that has passed through the filtering unit 40 may have a predetermined filtration purity range of 95% or higher.

Shaking method can be represented as a second example of the filtering unit 40, as shown in FIG. The filtering unit 40 according to the second example is passed through the shaker unit 42 and the shaker unit 42 to pass the filtering solution from the lysate by the shaker 421 stacked apart from each other in multiple stages. It may include a filtration unit for filtering the filtering solution to a predetermined filtration purity or more. Then, the filtering liquid that has passed through the filtering unit 40 may have a predetermined filtration purity range of 95% or higher. Here, the shake chae 421 may stack the 150 mesh first screen network, the 350 mesh second screen network, and the 500 mesh third screen network step by step.

The centrifugation method may be represented as a third example of the filtering unit 40 as shown in FIG. 4. The filtering unit 40 according to the third example is a first centrifuge 44 for centrifuging the lysate to extract a one-dimensional centrifugation solution, and centrifuging the one-dimensional centrifugation solution to extract a two-dimensional centrifugation solution. The second centrifugal separator 45 and the third centrifugal separator 46 for centrifuging the two-dimensional centrifugation liquid to extract the filtering liquid and the filtering liquid that has passed through the third centrifugal separator 46 have a predetermined filtration purity. It may include a filtration unit to filter the above. Then, the filtering liquid that has passed through the filtering unit 40 may have a predetermined filtration purity range of 95% or higher. Here, if the first centrifuge 44 adopts a decanter method, and the second centrifuge 45 employs a disk method, the third centrifuge 46 adopts a tubular method to remove the sludge from the solution. The recovery rate can be maximized.

In the above-described filtering unit 40, the filtration unit may include at least one of a filter press 43 and a micro filter 48. The filter press 43 can easily extract the filtering solution from the solution even if the concentration of the solution is high. The microfilter 48 may sequentially arrange a 0.45 micron filter, a carbon filter, and a 0.2 micron filter step by step.

At this time, the phenomenon that the expanded graphite contained in the sludge breaks while passing through the filtering means may occur. Accordingly, since the particles of the sludge are finely small, further separation of the fine sludge may be necessary. In particular, the sludge is lighter than the lysate and may remain on top of the lysate during centrifugation.

Accordingly, in one embodiment of the present invention, the filtering unit 40 is a floating separation tank 47 for injecting microbubbles into the filtering liquid discharged from the filtering unit or the filtering liquid discharged from the filtering unit so that sludge floats in the filtering liquid. It may further include. The filtering unit 40 may further include a radical unit (not shown) that changes the physical properties of the filtering liquid input to the floating separation tank 47. The radical unit (not shown) can facilitate the generation of microbubbles in the floating separation tank 47 by supplying radical water to the filtering liquid input to the floating separation tank 47. Then, the filtering liquid filtered by the floating separation tank 47 may have a predetermined filtration purity range of 98% to 99% or higher.

In the filtering liquid separation unit 60, polystyrene (PS) is extracted in a solid state by heating the filtering liquid directly or indirectly in a predetermined temperature range, and the solvent (MC) is a gas according to the vaporization of the filtering liquid by heating. State to be extracted.

The preset temperature range can be set from 60 degrees Celsius to 80 degrees Celsius. Within the preset temperature range, the vaporization point of the solvent (MC) is greater than that to promote the vaporization of the solvent, and combustion of the polystyrene (PS) can be prevented. The preset temperature range can be variously adjusted in units of 1 degree between 60 degrees Celsius and 80 degrees Celsius.

However, when the heating unit 70 or hot air is used in a preset temperature range, when outside the preset temperature range, the vaporization of the solvent MC is slowed, or the combustion of the polystyrene (PS) together with the vaporization of the solvent MC. There is a problem that a reaction occurs. In addition, when hot water is used in a preset temperature range, when outside the preset temperature range, the vaporization of the solvent MC is slowed or hot water is vaporized together with the vaporization of the solvent MC to lower the purity of the solvent MC. It has the problem of being able to do so and further separating the water vapor.

And the gaseous solvent MC is liquefied through the heat exchange unit 66 and can be recycled.

The filtering liquid separation unit 60 may be classified into the following five types according to the heating method of the filtering liquid.

The filtering liquid separation unit 60 according to the first example extracts polystyrene (PS) by directly heating the liquid storage tank 61 or the filtering liquid by the heating unit 70 as shown in FIGS. 5 and 6. Can.

The filtering liquid separation unit 60 according to the first example maintains a preset temperature range inside the liquid storage tank 61 in which the filtering liquid supplied from the filtering liquid storage tank 50 is accommodated, and the inside of the liquid storage tank 61. So that it may include a heating unit 70 for heating at least one of the liquid storage tank 61 and the filtering liquid.

Then, as the filtering liquid is directly or indirectly heated by the heating unit 70, the solid polystyrene (PS) is extracted from the filtering liquid, and the gaseous solvent (MC) is extracted from the filtering liquid according to the vaporization by heating. do.

The liquid storage tank 61 may be made of a sealed container. The liquid storage tank 61 may be provided with a liquid stirring unit 611 to stir the received filtering liquid and stably transfer heat of the heating unit 70 to the filtering liquid. In addition, the liquid storage tank 61 may be provided with an inclined collecting slope 612 so that the extracted polystyrene (PS) is collected to a predetermined position on the floor. In addition, the liquid storage tank 61 may be provided with a discharge screw unit 63 disposed at a predetermined position on the floor to discharge the collected polystyrene (PS). The discharge screw unit 63 is rotatably coupled to the second barrel 631 for collecting polystyrene (PS) and the second barrel 631 for rotation and discharge of the polystyrene (PS) as shown in FIG. It may include a second screw 632 and a second reducer 633 for rotating the second screw 632 at a predetermined reduction ratio. The discharge screw unit 63 includes a second heater 634 provided on the outer circumferential surface of the second barrel 631, and a second heater supplying hot air to the inside of the second barrel 631 or the liquid storage tank 61. At least one of the hot air fans 635 may be further included.

The heating unit 70 may include a heating unit 71 that heats the liquid storage tank 61 by heat dissipated by being coupled to the outer circumferential surface of the liquid storage tank 61 as shown in FIG. 5. Although not shown, the heating unit 71 may protrude into the liquid storage tank 61 to contact the filtering liquid. The heating unit 71 may be formed of at least one of linear, plate-shaped, and rod-shaped.

As shown in FIG. 6, the heating unit 70 may include a hot water tank 72 surrounding the liquid storage tank 61 and heating the liquid storage tank 61 by heat of the fluid filled therein. At this time, the heating unit 70 may further include a fluid heating unit 73 for supplying fluid to the hot water tank 72, circulating the fluid in the hot water tank 72, or heating the fluid in the hot water tank 72. have. The fluid of the fluid heating unit 73 may include water or air.

The filtering liquid separation unit 60 according to the first example may further include a drying unit 94 for drying the polystyrene (PS) discharged from the liquid storage tank 61. As the drying unit 94 is passed, it is possible to obtain polystyrene (PS) in a powder state or an incoat state. The drying unit 94 extracts the solvent MC remaining in the polystyrene (PS), and the extracted solvent MC is transferred to the heat exchange unit 66.

The filtering liquid separation unit 60 according to the first example liquefies the gaseous solvent (MC) generated in the liquid storage tank 61 and the drying unit 94 according to the vaporization of the filtering liquid by the heating unit 70. It may further include a heat exchange unit (66). The solvent MC liquefied by the heat exchange unit 66 can be recovered and recycled to the solvent storage tank 20.

The filtering liquid separation unit 60 according to the second example allows the filtering liquid to pass through the skew-flow unit as shown in FIG. 7, and directly heats the screw unit through the heating unit 70 to extract polystyrene (PS). can do.

The filtering liquid separation unit 60 according to the second example may include one or more screw units that heat the inside to maintain a predetermined temperature range while rotating the filtering liquid supplied from the filtering liquid storage tank 50.

The screw unit is inclined upward from the input side of the filtering liquid toward the discharge side so that the filtering liquid accommodated inside the screw unit is sufficiently heated, and the gaseous solvent (MC) is stably discharged.

The screw unit is a screw barrel through which the filtering liquid supplied from the filtering liquid storage tank 50 passes, a barrel screw rotatably coupled to the screw barrel, and a barrel reducer for rotating the filtering liquid at a predetermined reduction ratio. And, the inside of the screw barrel is provided on the outer peripheral surface of the screw barrel to maintain a predetermined temperature range may include a barrel heater to dissipate heat. The screw unit further comprises a barrel hot air fan that supplies hot air to the inside of the screw barrel, thereby promoting the extraction of polystyrene (PS) from the filtering solution, and preventing the extracted polystyrene (PS) from sticking to the screw barrel to prevent the screw barrel from sticking. In, polystyrene (PS) is stably discharged.

Then, as the filtering liquid is directly or indirectly heated by the barrel heater, the solid polystyrene (PS) is extracted from the filtering liquid, and the gaseous solvent (MC) is extracted from the filtering liquid according to the vaporization by heating.

In the filtering liquid separation unit 60 according to the second example, the screw unit may be divided into an input screw unit 62 and an discharge screw unit 63.

The input screw unit 62 is a first barrel 621 through which the filtering liquid supplied from the filtering liquid storage tank 50 passes, and a first screw rotatably coupled to the first barrel 621 to rotate and move the filtering liquid. 622, the first reduction gear 623 for rotating the first screw 622 at a predetermined reduction ratio, and the outer peripheral surface of the first barrel 621 so that the inside of the first barrel 621 maintains a predetermined temperature range It may include a first heater 624 to dissipate heat. The input screw unit 62 may further include a first hot air fan 625 that supplies hot air to the inside of the first barrel 621.

In addition, the discharge screw unit 63 is a second liquid (631) through which the filtering liquid and polystyrene (PS) passing from the input screw unit (62) pass, and the filtering liquid and the polystyrene (PS) for rotation and discharge A second screw 632 rotatably coupled to the two barrels 631, a second reducer 633 for rotating the second screws 632 at a predetermined reduction ratio, and provided on the outer circumferential surfaces of the second barrel 631 It may include a second heater (634). The discharge screw unit 63 may further include a second hot air fan 635 that supplies hot air to the inside of the second barrel 631.

The filtering liquid separation unit 60 according to the second example may further include a drying unit 94 for drying the polystyrene (PS) discharged from the screw unit. As the drying unit 94 is passed, it is possible to obtain polystyrene (PS) in a powder state or an incoat state. The drying unit 94 extracts the solvent MC remaining in the polystyrene (PS), and the extracted solvent MC is transferred to the heat exchange unit 66.

The filtering liquid separation unit 60 according to the second example comprises a heat exchange unit 66 for liquefying the gaseous solvent MC generated in the screw barrel and the drying unit 94 according to the vaporization of the filtering liquid by the barrel heater. It may further include. The solvent MC liquefied by the heat exchange unit 66 can be recovered and recycled to the solvent storage tank 20.

The filtering liquid separation unit 60 according to the third example allows the filtering liquid to pass through the screw unit, as shown in FIG. 8, and directly heats the screw unit or the filtering liquid through hot water to extract polystyrene (PS). have.

The filtering liquid separation unit 60 according to the third example rotates the input screw unit 62 for rotating the filtering liquid supplied from the filtering liquid storage tank 50 and the filtering liquid delivered from the input screw unit 62. The discharge screw unit 63, the input screw unit 62, and the discharge screw unit 63 are immersed in a hot water storage tank 80 in which hot water is accommodated to maintain a predetermined temperature range, and hot water and filtering. It may include a mixing net 64 mounted to at least one of the input screw unit 62 and the discharge screw unit 63 so that the liquid is in direct or indirect contact.

Then, as the filtering liquid is directly or indirectly heated by hot water, the solid polystyrene (PS) is extracted from the filtering liquid, and the gaseous solvent (MC) is extracted from the filtering liquid according to the vaporization by heating.

The input screw unit 62 is a first barrel 621 through which the filtering liquid supplied from the filtering liquid storage tank 50 passes, and a first screw rotatably coupled to the first barrel 621 to rotate and move the filtering liquid. 622, the first reduction gear 623 for rotating the first screw 622 at a predetermined reduction ratio, and the outer peripheral surface of the first barrel 621 so that the inside of the first barrel 621 maintains a predetermined temperature range It may include a first heater 624 to dissipate heat. The input screw unit 62 may further include a first hot air fan 625 that supplies hot air to the inside of the first barrel 621.

In addition, the discharge screw unit 63 is a second liquid (631) through which the filtering liquid and polystyrene (PS) passing from the input screw unit (62) pass, and the filtering liquid and the polystyrene (PS) for rotation and discharge A second screw 632 rotatably coupled to the two barrels 631, a second reducer 633 for rotating the second screws 632 at a predetermined reduction ratio, and provided on the outer circumferential surfaces of the second barrel 631 It may include a second heater (634). The discharge screw unit 63 may further include a second hot air fan 635 that supplies hot air to the inside of the second barrel 631.

The hot water storage tank 80 may be made of a sealed container. The hot water storage tank 80 may be provided with a heating unit 70 for heating hot water.

In the mixing network 64, the filtering solution and hot water are brought into contact with each other so that the filtering solution is stably separated into polystyrene (PS) and solvent (MC).

The filtering liquid separation unit 60 according to the third example may further include a dehydration unit 93 for removing moisture from the polystyrene (PS) discharged from the discharge screw unit (63). The moisture discharged from the dewatering unit 93 is transferred to the hot water storage tank 80 and can be recycled. The generation of water vapor in the drying unit 94 can be prevented as the dehydration unit 93 passes. The dehydration unit 93 extracts the solvent MC remaining in the polystyrene (PS), and the extracted solvent MC is transferred to the heat exchange unit 66.

The filtering liquid separation unit 60 according to the third example may further include a drying unit 94 for drying the polystyrene (PS) discharged from the discharge screw unit 63 or the dehydration unit 93. As the drying unit 94 is passed, it is possible to obtain polystyrene (PS) in a powder state or an incoat state. The drying unit 94 extracts the solvent MC remaining in the polystyrene (PS), and the extracted solvent MC is transferred to the heat exchange unit 66.

The filtering liquid separation unit 60 according to the third example is a gaseous solvent (MC) generated in the first barrel 621, the second barrel 631, and the drying unit 94 according to the vaporization of the filtering liquid by hot water. ) May further include a heat exchange unit (66) to liquefy. The solvent MC liquefied by the heat exchange unit 66 can be recovered and recycled to the solvent storage tank 20.

The filtering liquid separation unit 60 according to the fourth example, as shown in FIGS. 9 and 10, extracts polystyrene (PS) by heating the filtering liquid by hot water through injection of at least the filtering liquid among the hot water and the filtering liquid. Can.

The filtering liquid separation unit 60 according to the fourth example includes a hot water storage tank 80 in which hot water is accommodated so that the inside is maintained at a preset temperature range, and a filtering liquid storage tank in the hot water storage tank 80 or inside the hot water surface ( 50) a liquid ejecting unit (65) for spraying the filtering liquid stored in the, and a carrying unit for taking out the floating matter floating in the hot water of the hot water storage tank (80) according to the vaporization of the filtering liquid to the outside of the hot water storage tank (80). It can contain.

Then, as the filtering liquid is directly or indirectly heated by hot water, the solid polystyrene (PS) is extracted from the filtering liquid, and the gaseous solvent (MC) is extracted from the filtering liquid according to the vaporization by heating.

The hot water storage tank 80 may be made of a sealed container. The hot water storage tank 80 may be provided with a heating unit 70 to heat the interior. 10, the hot water storage tank 80 may include a hot water reaction tank 80-1 and a hatch 80-2 for opening and closing the hot water reaction tank 80-1.

The liquid injection unit 65 may spray the filtering liquid in a mist form.

As illustrated in FIG. 9, the transport unit may include a float transport unit 84 that discharges polystyrene (PS) suspended in hot water from one side of the hot water storage tank 80. The floating material transport unit 84 may exhibit a watermill type. As illustrated in FIG. 9, the discharge unit may further include an discharge screw unit 63 for discharging the polystyrene (PS) delivered from the floating material transportation unit 84. The discharge screw unit 63 is rotatable in the second barrel 631 in which polystyrene (PS) delivered from the floating material transport unit 84 is collected, and in the second barrel 631 for rotation and discharge of the polystyrene (PS). The second screw 632 is coupled to the second screw 632, and includes a second reducer 633 for rotating the second screw 632 at a predetermined reduction ratio, and a second heater 634 provided on the outer circumferential surface of the second barrel 631 ) And a second hot air blower 635 for supplying hot air to the inside of the second barrel 631.

As illustrated in FIG. 10, the transport unit may include a conveyor unit 85 that discharges moisture while transporting the polystyrene (PS) containing moisture.

The filtering liquid separation unit 60 according to the fourth example may further include an auxiliary tank 80a in which hot water is stored.

The filtering liquid separation unit 60 according to the fourth example recovers hot water and delivers it to the auxiliary tank 80a, or hot water from the auxiliary tank 80a or hot water from the hot water storage tank 80 to the hot water spraying unit 82. A hot water pumping unit 81 for transferring may be further included.

The filtering liquid separation unit 60 according to the fourth example includes a hot water spray unit 82 for spraying hot water having a predetermined temperature range on at least one of the filtering liquid and the hot water surface inside the hot water storage tank 80, It may further include at least one of the hot water circulation unit 83 for moving the floating material floating on the surface of the hot water toward the carrying unit.

The hot water spraying unit 82 may spray hot water in a mist form.

The hot water circulation unit 83 may be immersed in hot water in the hot water storage tank 80 or disposed above the hot water to move the floating matter on the surface of the hot water to the floating material transport unit 84.

The filtering liquid separation unit 60 according to the fourth example may further include a dehydration unit 93 for removing moisture from the polystyrene (PS) discharged from the carrying unit. The moisture discharged from the dewatering unit 93 is transferred to the hot water storage tank 80 or the auxiliary tank 80a and can be recycled. The generation of water vapor in the drying unit 94 can be prevented as the dehydration unit 93 passes. The dehydration unit 93 extracts the solvent MC remaining in the polystyrene (PS), and the extracted solvent MC is transferred to the heat exchange unit 66.

The filtering liquid separation unit 60 according to the fourth example may further include a drying unit 94 for drying the polystyrene (PS) discharged from the discharging unit or the dehydration unit 93. As the drying unit 94 is passed, it is possible to obtain polystyrene (PS) in a powder state or an incoat state. The drying unit 94 extracts the solvent MC remaining in the polystyrene (PS), and the extracted solvent MC is transferred to the heat exchange unit 66.

The filtering liquid separation unit 60 according to the fourth example is a gaseous solvent generated in the hot water storage tank 80, the discharge unit, the dehydration unit 93, and the drying unit 94 according to the vaporization of the filtering liquid by the hot water. It may further include a heat exchange unit (66) for liquefying (MC). The solvent MC liquefied by the heat exchange unit 66 can be recovered and recycled to the solvent storage tank 20.

The filtering liquid separation unit 60 according to the fifth example may extract polystyrene (PS) by heating the filtering liquid by spraying hot air to the injected filtering liquid as shown in FIG. 11.

The filtering liquid separation unit 60 according to the fifth example includes a hot air reaction tank 100, a liquid injection unit 65 for spraying filtering liquid inside the hot air reaction tank 100, and a hot air reaction tank 100 or It may include a hot air spray unit 106 for spraying hot air having a predetermined temperature range in the filtering solution.

Then, as the filtering liquid is directly or indirectly heated by the hot air, the solid polystyrene (PS) is extracted from the filtering liquid, and the gaseous solvent (MC) is extracted from the filtering liquid according to the vaporization by the hot air.

Hot air reaction tank 100 may be made of a sealed container. Although not shown, the hot air reaction tank 100 may be provided with a heating unit 70 to heat the interior.

The liquid injection unit 65 may spray the filtering liquid in a mist form.

The filtering liquid separation unit 60 according to the fifth example may further include a hot air unit 105 that generates hot air having a predetermined temperature range and transmits the hot air to the hot air injection unit 106.

The filtering liquid separation unit 60 according to the fifth example is a powder that transports polystyrene (PS) generated in the hot air reaction tank 100 to the cyclone 102 or the transfer storage tank 104 according to the vaporization of the filtering liquid by the hot air. The blower 101 may be further included.

The filtering liquid separation unit 60 according to the fifth example may further include a cyclone 102 that extracts a gaseous solvent (MC) by applying centrifugal force to the polystyrene (PS) delivered from the powder blower 101. . The solvent MC extracted from the cyclone 102 is transferred to the heat exchange unit 66.

The filtering liquid separation unit 60 according to the fifth example may further include a delivery blower 103 for transporting polystyrene (PS) generated in the cyclone 102 to the delivery storage tank 104.

The filtering liquid separation unit 60 according to the fifth example may further include a delivery reservoir 104 in which polystyrene (PS) delivered from the powder blower 101 or the delivery blower 103 is stored.

The filtering liquid separation unit 60 according to the fifth example is a powder blower (101), a cyclone (102), a delivery blower (103), a powder container for reducing the polystyrene (PS) delivered through the delivery reservoir (104) ( 107).

The filtering liquid separation unit 60 according to the fifth example may further include an extruder 108 extruding the polystyrene (PS) applied in the powder container 107.

The filtering liquid separation unit 60 according to the fifth example uses gaseous solvent (MC) generated in the hot air reaction tank 100, the cyclone 102, and the transfer reservoir 104 according to the vaporization of the filtering liquid by the hot air. It may further include a heat exchange unit 66 to liquefy. The solvent liquefied by the heat exchange unit 66 can be recycled to the solvent storage tank 20.

In addition, in the filtering liquid separation unit 60, polystyrene (PS) is extracted in a solid state according to the mixing of the filtering liquid and the anti-solvent (G), and the solvent (MC) in the filtering liquid separation unit 60 is used as the filtering liquid. Depending on the mixing of the medium (G), the anti-solvent (G) may be extracted in a mixed liquid state.

And the solvent (MC) of the liquid ecology in which the anti-solvent (G) is mixed can be fractionally distilled into the gas-based solvent (G) and the gas-based solvent (MC) by the difference in boiling point while passing through the fractional distiller (92). have. In addition, the gaseous anti-solvent (G) is liquefied through the liquefaction unit (80-5) and can be recycled, and the gaseous solvent (MC) is liquefied through the heat exchange unit (66) and can be recycled.

The filtering liquid separation unit 60 may be divided into a sixth example according to an extraction method using an anti-solvent (G).

The filtering liquid separation unit 60 according to the sixth example may extract polystyrene (PS) by mixing an anti-solvent (G) in the filtering liquid as shown in FIG. 12.

The filtering solution separation unit 60 according to the sixth example mixes the filtering solution accommodated in the filtering solution storage tank 50 with an anti-solvent (G) to produce an anti-solvent mixture, and extracts polystyrene (PS) from the anti-solvent mixture. An anti-solvent extraction tank (80-4) and polystyrene (PS) may be extracted and the residual anti-solvent mixture may include a fractional distiller (92) for fractional distillation with an anti-solvent (G) and a solvent (MC) by boiling point difference. have.

Then, the polystyrene (PS) in the solid state is extracted from the filtering solution according to the mixing of the anti-solvent (G) and the filtering solution, and the gaseous solvent (MC) and the gaseous state according to the fractional distillation by the fractional distiller (92). The anti-solvent (G) is extracted respectively.

The filtering liquid separation unit 60 according to the sixth example may further include an anti-solvent storage tank 80-3 in which the anti-solvent (G) is stored. The anti-solvent storage tank 80-3 may supply the anti-solvent (G) to the anti-solvent extraction tank 80-4 at a preset mixing ratio. The filtering liquid storage tank 50 may also supply the filtering liquid to the anti-solvent extraction tank 80-4 at a preset mixing ratio.

The filtering liquid separation unit 60 according to the sixth example may further include a liquefaction unit 80-5 that liquefies the gaseous anti-solvent G generated in the fractionation distiller 92. The anti-solvent (G) liquefied by the liquefaction unit (80-5) is recovered in the anti-solvent storage tank (80-4) and can be recycled.

The filtering liquid separation unit 60 according to the sixth example may further include a compressor 91 for compressing the polystyrene extracted from the anti-solvent storage tank 80-3. The anti-solvent mixture discharged from the compressor 91 may be delivered to a fractional distiller 92 or an anti-solvent extraction tank 80-4.

The filtering liquid separation unit 60 according to the sixth example may further include a drying unit 94 for drying the polystyrene (PS) discharged from the compressor 91 or the anti-solvent extraction tank 80-4. As the drying unit 94 is passed, it is possible to obtain polystyrene (PS) in a powder state or an incoat state. The drying unit 94 extracts the solvent MC remaining in the polystyrene (PS), and the extracted solvent MC is transferred to the heat exchange unit 66.

The filtering liquid separation unit 60 according to the sixth example is a heat exchange unit liquefying a gaseous solvent (MC) generated in the fractional distiller 92 and a gaseous solvent (MC) generated in the drying unit 94 ( 66) may be further included. The solvent MC liquefied by the heat exchange unit 66 can be recovered and recycled to the solvent storage tank 20.

According to the polystyrene extraction system for recycling of the flame retardant styrofoam, high-purity polystyrene (PS) can be extracted by separating and extracting the flame retardant and polystyrene (PS) from the flame retardant styrofoam, and helping to recycle the flame retardant styrofoam to prevent environmental pollution and recycling It can promote the creation of new profits in the market.

In addition, the flame retardant styrofoam can be stably sourced through an incoat through reduction of the flame retardant styrofoam.

In addition, it is possible to stabilize the stirring of the raw material and the solvent (MC) in the dissolving tank 30 through the dissolution stirring unit 31.

In addition, it is possible to accurately mix the raw material and the solvent (MC) by limiting the weighing unit and the preset mixing ratio, and to clearly combine the solvent (MC) and the polystyrene (PS).

In addition, the filtering solution can be stably extracted from the dissolved solution through the filtering unit 40, and the purity of the filtering solution can be improved to 95% or more.

In addition, it is possible to stabilize the extraction and discharge of sludge from the lysate through the filtering unit (40).

In addition, the separation of the filtering solution and the sludge from the solution can be stabilized through centrifugation of the solution.

In addition, through the floating separation tank 47, the fine sludge can be stably floated in the filtering liquid to further improve the purity of the filtering liquid, and the generation of microbubbles in the filtering liquid which is an organic solvent through a radical (not shown). Can promote.

In addition, through the filtering liquid separation unit 60, the solid state polystyrene (PS) can be extracted from the filtering liquid with high purity, and the gaseous solvent (MC) can be separated and extracted from the filtering liquid.

In addition, by using the direct or indirect heating of the filtering liquid in the filtering liquid separation unit 60, the vaporization of the solvent (MC) in the filtering liquid can be promoted.

Further, in the filtering liquid separation unit 60, hot water mixed for heating of the filtering liquid can be separated, and polystyrene (PS) mixed in the hot water can be stably extracted.

In addition, extraction of polystyrene (PS) from the filtering solution may be simplified by mixing the filtering solution and the anti-solvent (G) in the filtering solution separation unit 60.

In addition, the polystyrene (PS) may be separated and extracted with an antisolvent (G) and a solvent (MC) using a difference in boiling point according to fractional distillation of the antisolvent mixture removed.

In addition, the vaporized anti-solvent (G) and the vaporized solvent (MC) can be stored separately to liquefy stably, and the liquefied anti-solvent (G) and liquefied solvent (MC) can be recycled.

In addition, the heating of the filtering liquid by the hot air in the filtering liquid separation unit 60 prevents mixing of the polystyrene (PS) and moisture extracted from the filtering liquid, and increases the purity of the extracted polystyrene (PS) to stably increase the polystyrene ( PS).

Although the preferred embodiments of the present invention have been described with reference to the drawings as described above, those skilled in the art may vary the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. Can be modified or changed.

10: raw material hopper 11: incoat grinder 12: incoat maker
20: solvent storage tank 30: dissolution tank 31: dissolution stirring unit
C1: First meter C2: Second meter PLC: Weighing controller
40: filtering unit 41: bag filter unit 411: bag filter
42: shake shake unit 421: shake shake 43: filter press
44: first centrifuge 45: second centrifuge 46: third centrifuge
47: floating separation tank 48: micro filter 50: filtering liquid storage tank
60: filtering liquid separation unit 61: liquid storage tank 611: liquid stirring
612: collection slope 62: input screw unit 621: first barrel
622: first screw 623: first reduction gear 624: first heater
625: first hot air fan 63: discharge screw unit 631: second barrel
632: 2nd screw 633: 2nd reduction gear 634: 2nd heater
635: second hot air fan 64: mixing net 65: liquid spray unit
66: heat exchange unit 70: heating unit 71: heating unit
72: hot water tank 73: fluid heating unit 80: hot water storage tank
80a: auxiliary tank 81: hot water pumping unit 82: hot water injection unit
83: hot water circulation unit 84: floating material transport unit 85: conveyor unit
80-1: hot water reaction tank 80-2: hatch 80-3: anti-solvent storage tank
80-4: anti-solvent extraction tank 80-5: liquefaction unit 91: compressor
92: fractional distiller 93: dehydration unit 94: drying unit
100: hot air reaction tank 101: powder blower 102: cyclone
103: transmission blower 104: transmission storage tank 105: hot air unit
106: hot air spray unit 107: powder reducer 108: extruder
PS: Polystyrene MC: Solvent PSC: Extrudate
G: antisolvent

Claims (13)

At least one dissolution tank for stirring the raw material produced by crushing the reduced flame retardant styrofoam and a solvent for dissolving the raw material at a predetermined mixing ratio to generate a solution;
A filtering unit extracting a filtering solution in which the solvent and the polystyrene contained in the raw material are mixed from the solution;
A filtering liquid storage tank in which the filtering liquid is stored; And
And a filtering solution separation unit separating the filtering solution into the solvent and the polystyrene.
According to claim 1,
The filtering solution in the filtering unit,
A polystyrene extraction system characterized in that the lysate is extracted as it passes through a multi-stage filtering means and is filtered over a predetermined filtration purity.
According to claim 2,
The filtering means,
A polystyrene extraction system, characterized in that the filtering solution is extracted using any one of a bag filter method, a shake method, and a centrifugal separation method.
The method of claim 2 or 3,
The filtering unit,
Polystyrene extraction system characterized in that it is provided; flotation separation tank for floating by extracting the fine sludge from the filtering liquid using a microbubble.
According to claim 1,
The filtering liquid separation unit,
A liquid storage tank in which the filtering liquid supplied from the filtering liquid storage tank is accommodated; And
And a heating unit configured to heat at least one of the liquid storage tank and the filtering liquid so that the inside of the liquid storage tank maintains a predetermined temperature range.
According to claim 1,
The filtering liquid separation unit,
Includes; one or more screw units to heat the inside to maintain a predetermined temperature range while rotating the filtering liquid supplied from the filtering liquid storage tank;
The screw unit,
A screw barrel through which the filtering liquid supplied from the filtering liquid storage tank passes;
A barrel screw rotatably coupled to the screw barrel to rotate and move the filtering solution;
A barrel reducer for rotating the barrel screw at a predetermined reduction ratio; And
Polystyrene extraction system characterized in that it comprises; a barrel heater that is provided on the outer peripheral surface of the screw barrel to dissipate heat so as to maintain a predetermined temperature range inside the screw barrel.
According to claim 1,
The filtering liquid separation unit,
An input screw unit that rotates and moves the filtering liquid supplied from the filtering liquid storage tank;
A discharge screw unit that rotates and moves the filtering liquid delivered from the input screw unit;
A hot water storage tank in which the input screw unit and the discharge screw unit are immersed to receive hot water to maintain a predetermined temperature range inside; And
And a mixing network mounted on at least one of the input screw unit and the discharge screw unit so that the hot water and the filtering liquid contact directly or indirectly.
According to claim 1,
The filtering liquid separation unit,
A hot water storage tank in which hot water is accommodated so that the inside is maintained at a preset temperature range;
A liquid spray unit for spraying the filtering liquid stored in the filtering liquid storage tank to the hot water storage tank or the hot water surface; And
Polystyrene extraction system comprising a; a discharge unit for taking out the suspended matter floating in the hot water of the hot water storage tank to the outside of the hot water storage tank according to the evaporation of the filtering liquid.
The method of claim 8,
The filtering liquid separation unit,
A hot water spray unit for spraying the hot water having a preset temperature range on at least one of the filtering solution and the hot water surface in the hot water storage tank;
A hot water circulation unit for moving the floating material floating on the hot water surface toward the carrying unit; And
A dewatering unit that dehydrates the polystyrene carried out by the carrying unit;
Polystyrene extraction system, characterized in that it further comprises at least one of.
According to claim 1,
The filtering liquid separation unit,
Hot air reaction tank;
A liquid spray unit for spraying the filtering liquid into the hot air reaction tank;
A hot air injection unit for spraying hot air having a predetermined temperature range in the hot air reaction tank or in the filtering liquid; And
Polystyrene extraction system comprising a; a powder blower for discharging the polystyrene generated in the hot air reaction tank according to the vaporization of the filtering liquid by hot air.
The method of claim 10,
The filtering liquid separation unit,
A cyclone that extracts the solvent in a gaseous state by acting a centrifugal force on the polystyrene delivered from the powder blower; And
A powder container for reducing the polystyrene delivered from the powder blower;
Polystyrene extraction system, characterized in that it further comprises at least one of.
According to claim 1,
The filtering liquid separation unit,
An anti-solvent extraction tank for mixing the filtering solution contained in the filtering solution storage tank with an anti-solvent to produce an anti-solvent mixture, and extracting the polystyrene from the anti-solvent mixture; And
And a fractional distiller which fractionally distills the remaining anti-solvent mixture after the polystyrene is extracted into the anti-solvent and the solvent by a boiling point difference.
The method according to any one of claims 5 to 12,
The filtering liquid separation unit,
Polystyrene extraction system characterized in that it is provided; heat exchange unit for liquefying the solvent in the gaseous state.

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