JP2941781B1 - Wet separation method and apparatus - Google Patents

Abstract

Abstract: PROBLEM TO BE SOLVED: To contain a large amount of a specific object (solid or liquid) having the same specific gravity as a liquid from among the objects (objects to be processed) having a wide specific gravity distribution with a specific gravity of 1 as a center. The fractions are selectively recovered with high purity. SOLUTION: An apparatus for separating an object to be processed upward or downward by using a centrifugal force caused by a swirling flow of the liquid to be processed to separate the object to be processed upward or downward by a difference in specific gravity between the object and the liquid is used. When sorting the processed material, the amount of liquid discharged below the apparatus is made larger than the amount of liquid discharged above the apparatus, so that the object to be processed (solid or liquid) having the same specific gravity as the liquid Is recovered from the liquid discharged above the apparatus. Specifically, in the liquid cyclone 14c, the ratio S1 / S2 of the cross-sectional area S1 of the upper extraction pipe (immersion pipe) 18c to the cross-sectional area S2 of the lower extraction pipe 20c is 0.2 to 1.3, desirably. , 0.25 to 1.0.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wet separation method in which an object to be treated is separated by a difference in the specific gravity between the object and the liquid by utilizing the centrifugal force of the swirling flow of the liquid to be treated. The present invention relates to a method for recovering a fraction containing a large amount of a substance to be treated (solid or liquid) with high purity, and a wet separation apparatus using the method, for example, a waste plastic separation apparatus.

[0002]

2. Description of the Related Art Wet separation is a technique widely required in the industry, such as solid-liquid separation and liquid-liquid (oil-water) separation. In addition, this technology is used for separating waste plastics, and is an indispensable technology for turning waste plastics into oil by thermal decomposition and recycling various wastes such as RDF (garbage solid fuel). Conventional techniques for wet separation include liquid cyclones (hydrocyclones), decanters, etc., all of which are liquid (water).
Is a method in which the specific gravity is divided into two at the boundary by light weight.

For example, when separating waste plastics using a liquid cyclone (hydrocyclone), as shown in FIG. 10, mixed waste plastic crushed pieces which have been crushed in advance and city water (or saline) are separated. The mixed waste plastic fragment-containing liquid in the tank 10 is charged into the liquid cyclone 14 by the pump 12.
Is supplied to the inlet 16 of the liquid to be treated. Hydrocyclone 14
In the inside, the supplied liquid forms a swirling flow, and a plastic (light substance) having a lower specific gravity than water (or saline) is provided in a central portion, and a plastic (heavy substance) having higher specific gravity than water (or saline) is present in the center. Gather outside, respectively. Under the general operating conditions of the hydrocyclone, 70 to 90% of the supply liquid is drained from above, and the most part of the water (or saline) and the central part are discharged from the upper extraction pipe (immersion pipe) 18. The collected light materials are discharged. On the other hand, heavy substances and remaining water (or saline) are discharged from the lower extraction pipe 20. The liquid containing the light substance and the liquid containing the heavy substance are respectively separated into solid-liquid separators 22, 2
The solid component (separated plastic) which has been introduced into and separated into a solid and a liquid is used as an upper recovery product and a lower recovery product for recycling and the like, or disposed of. The liquid separated by the solid-liquid separators 22 and 24 is
Circulates in the plastic-containing liquid tank 10.

[0004] In the conventional separation of waste plastic using a hydrocyclone, for example, polyvinyl chloride (PV) is used.
C, vinyl chloride), polyethylene terephthalate (PE
T), polystyrene (PS), polyethylene (PE),
When attempting to recover PS, PE, and PP, which are suitable for oiling, from a waste plastic mixture composed of polypropylene (PP), most of PS, which has a slightly higher specific gravity than water, is almost the same as PE, PP, which has a lower specific gravity than water. It was not discharged to the lighter side (upper side), but was discharged to the same heavy side (lower side) as PVC and PET (unsuitable for oiling) having a higher specific gravity than water. Also, it was impossible to selectively recover PS, which is a material suitable for oiling.

Further, Japanese Patent Publication No. 57-41983 discloses a configuration in which a lower cyclone of a straight cylindrical shape or a conical cylindrical shape is provided so as to surround a lower half of an upper cyclone. It describes that a swirling flow is applied to re-separate heavy matter discharged from below the upper cyclone, thereby improving the accuracy of separation. Japanese Utility Model Application Laid-Open No. 58-91460 discloses that, in a cyclone in which a guide tube (immersion tube) is a double tube, the volume of an annular space between two guide tubes (immersion tubes) above a flange is reduced from below. By narrowing down to the top, 2
A configuration that facilitates collection of a sample passing between the guide tubes (immersion tubes) is described.

[0006]

Basically, a conventional hydrocyclone (hydrocyclone) separates an object by a centrifugal force caused by a swirling flow and a specific gravity difference between the object to be processed (object to be processed) and the liquid. . Therefore, only light-weight two components could be separated based on the specific gravity of the liquid. therefore,
To recover a medium with a specific gravity from a liquid to be treated containing a mixture of particles having three or more different specific gravities (including particles having a medium specific gravity in addition to particles having a light specific gravity) It was necessary to perform the treatment using two types of liquids having specific gravity before and after the particles. As an example, in order to recover PS from a mixture of crushed pieces of PE having a specific gravity smaller than water, PS having a specific gravity slightly higher than water, and PVC having a specific gravity higher than water, first, the PE is separated from the mixture by a difference in specific gravity with water.
And then using a liquid (e.g., saline) having a higher specific gravity than PS and a lower specific gravity than PVC,
It was necessary to separate PS from C.

Further, the apparatus described in Japanese Patent Publication No. 57-41983 is capable of re-fractionating heavy substances discharged from below the upper cyclone. PP, PE, PS) can be separated and collected. However, it has drawbacks such as the necessity of separately supplying a clear liquid and the need to control a number of water supply and drainage systems in conjunction with each other. Appropriate. Also,
The apparatus described in Japanese Utility Model Application Laid-Open No. 58-91460 can be separated into three types: central dip tube discharge, outer dip tube discharge, and lower discharge. However, since it is necessary to determine the cross-sectional area of the immersion pipe in accordance with the amount of withdrawn water, the gap between the central immersion pipe and the outer immersion pipe becomes small, and large particles (particle diameter: 2 to 20 mm) cannot be treated. Furthermore, the combined output of the two dip tubes is the same as the upper discharge of a cyclone of the basic type (the dip tube is a single tube). Therefore, when waste plastics are separated for the purpose of recovering fuel suitable material (oil suitable material: PP, PE, PS), the upward recovery rate of PS is low and is not suitable as a separation device. In addition, since light materials descend on the surface of the immersion tube with a certain layer distribution,
It will be included in both the central dip tube effluent and the outer dip tube effluent. Therefore, it is not suitable as an apparatus for collecting a sample near the liquid specific gravity. As described above, in the conventional technology, there are some which can be classified into three types, but it is impossible to practically use it as a device for recovering one having an intermediate specific gravity due to problems such as difficulty in setting operating conditions. there were.

Further, a waste plastic mixture (main material: P
When it is intended to recover fuel-compatible plastics (PP, PE, PS) from P, PE, PS, PVC, PET), most of them are PV because PS has a higher specific gravity than water.
C, it was discharged to the same heavy side (below) as PET, and it was not possible to efficiently separate fuel-compatible materials. Here, as a method of improving the recovery rate of PS, as shown in FIG. 11, the lower extraction pipe 20a of the liquid cyclone 14a is connected to the liquid inlet 16b to be processed of the liquid cyclone 14b, and the liquid cyclone is multistaged ( In FIG. 11, a two-stage case is shown as an example), and an upper extraction tube (immersion tube) of the hydrocyclone 14a is shown.
A part of PP, PE and PS is recovered from 18a, and a mixture containing most of PVC, PET and PS discharged from the lower extraction pipe 20a of the hydrocyclone 14a is fractionated again by the hydrocyclone 14b, A method of further recovering a part of PS from the upper extraction pipe 18b (immersion pipe) is considered. However, when the particle size of the object to be treated is large (2 to 30 mm) as in the case of waste plastic, it is necessary to increase the flow rate of each pipe (upper pipe, lower pipe) as much as possible in order to prevent blockage of the pipe. is there. However, the normal operation condition of the liquid cyclone is that, as described above, the upper drainage amount is 70 to 90% of the supply liquid amount, and for example, as shown in FIG. 700
Assuming that the lower limit of each pipe flow rate at L / min is 100 L / min, the lower extraction pipe 2
The amount of water from 0b becomes the minimum of 28 L / min, which is far below the lower limit that can prevent the blockage of the pipe. Therefore, a multi-stage system as shown in FIG. 11 has not been conventionally adopted. Note that, in FIG. 11, components such as a tank, a pump, and a solid-liquid separator are omitted.

As a method for recovering PS (medium heavy substance) having a specific gravity slightly higher than that of water from the top together with PP and PE (light substance), for example, the specific gravity of PS is increased by using a saline solution to increase the specific gravity of PS. Is smaller than the liquid specific gravity,
There is a method to increase the recovery rate of PS to PP and PE,
Large amounts of salt are required. For example, in order to separate PS from heavy substances (PVC, PET) (recover PS upward by 95% or more) under the same conditions as Comparative Example 1 described later, a salt concentration of 6 w / v is used.
% (Liquid specific gravity 1.05) or more, and PS
In order to recover% above, a salt concentration of 13 w / v% or more is required (the salt concentration of seawater is 3.0 to 3.5 w / v%). In addition, it is necessary to wash the treated and recovered product with water, which significantly reduces the economics of the treatment process.

The present invention has been made in view of the above points, and an object of the present invention is to use a centrifugal force caused by a swirling flow of a liquid to be treated to determine a difference in specific gravity between the substance to be treated and the liquid. In the wet fractionation for separating an object to be treated (object to be treated), a specific object to be treated (object to be treated) having a specific gravity similar to that of a liquid is selected from among objects to be treated (objects to be treated) having a wide specific gravity distribution centering on a specific gravity of 1. It is an object of the present invention to provide a wet fractionation method and apparatus capable of selectively recovering a fraction containing a large amount of solid or liquid) with high purity. Another object of the present invention is to separate waste plastics using the above-mentioned wet separation method and apparatus, so that P (medium heavy matter) having a specific gravity slightly higher than that of water can be obtained.
The recovery rate on the P, PE (light material) side can be increased,
Thereby, a wet separation method capable of efficiently recovering a suitable fuel material (oil suitable material: PP, PE, PS) from a waste plastic mixture (main material: PP, PE, PS, PVC, PET) using city water, and It is to provide a device.

[0011]

In order to achieve the above object, a wet separation method according to the present invention utilizes a centrifugal force of a swirling flow of a liquid to be treated to separate a liquid to be treated (solid or liquid) from a liquid. Using a device that separates an object (solid or liquid) upward or downward based on the difference in specific gravity, when separating an object to be processed having a specific gravity similar to that of a liquid, the amount of liquid discharged below the apparatus is reduced. An object (solid or liquid) having a specific gravity similar to that of the liquid is recovered with high purity from the liquid discharged above the apparatus by increasing the amount of liquid discharged above the apparatus. (See FIGS. 1 to 6 and 9).

In the above method of the present invention, the amount of the liquid discharged above the apparatus is preferably 1 to 40%, more preferably 10 to 30% of the amount of the liquid to be processed supplied to the apparatus. . Further, as the device used in the above method,
Hydrocyclones are preferred. Further, as the liquid to be treated,
The method of the present invention can be applied to the separation of waste plastic using a mixed waste plastic fragment containing liquid containing polystyrene (PS). The method of the present invention can be applied to solid-liquid separation and liquid-liquid (oil-water) separation other than waste plastic separation.

In the method of the present invention, when a plastic (for example, PS) having a specific gravity similar to that of water is separated using a multistage liquid cyclone provided in a plurality of units in series, the uppermost liquid cyclone is used. A liquid containing mixed waste plastic fragments (for example, PP, PE, PS, PVC, P
ET) to increase the amount of liquid discharged below the hydrocyclone compared to the amount of liquid discharged above, so that plastic (eg, PS) having the same specific gravity as water can be obtained.
Is recovered from the liquid discharged upward, and the liquid discharged downward is supplied to the liquid inlet of the lower liquid cyclone to be treated, and the same operation as the liquid cyclone at the uppermost liquid cyclone is repeated in the lower liquid cyclone. A plastic having a specific gravity similar to that of water (eg, PS) is recovered from the liquid discharged upward, and a plastic having a specific gravity similar to that of water (eg, P) is recovered.
(S) is improved (FIG. 5).
reference).

Further, the method of the present invention uses a multi-stage liquid cyclone provided in a plurality of units in series to convert a plastic (eg, PS) having a specific gravity similar to that of water into a plastic (eg, PP, PP) having a specific gravity smaller than that of water. In the separation process together with the PE), a liquid containing mixed waste plastic fragments containing a plastic having a specific gravity similar to that of water and a plastic having a specific gravity smaller than that of water (for example, PP, By supplying PE, PS, PVC, PET, and making the amount of liquid discharged below the hydrocyclone larger than the amount of liquid discharged above, the plastic having a specific gravity substantially equal to that of water (for example, PS)
Is recovered from the liquid discharged upward, and the liquid discharged downward is supplied to the liquid inlet of the lower liquid cyclone to be processed. In the lower liquid cyclone, the amount of liquid discharged upward is discharged downward. By increasing the liquid volume compared to the liquid volume, plastics having a lower specific gravity than water (eg, PP and PE) are recovered from the liquid discharged upward, and a plastic having a specific gravity similar to that of water and a specific gravity lower than water are recovered. It is characterized by improving the recovery rate of the total amount of plastic (for example, PP, PE, PS) (see FIG. 6).

The wet separation apparatus of the present invention has a tangential liquid inlet in the upper part of the main body and an upper end provided in the upper part of the main body such that the tip protrudes from the upper surface of the main body to form an upper outlet. In a liquid cyclone having a discharge pipe (immersion pipe), a lower discharge port at the lower part of the main body, and a lower discharge pipe connected to the lower discharge port, the liquid is discharged below the liquid cyclone.
The amount of liquid discharged is larger than the amount of liquid discharged upward,
Is the liquid whose specific gravity is about the same as the liquid discharged upward?
Upper extraction pipe (immersion pipe) so that it can be recovered from
The ratio S1 / S2 of the cross-sectional area S1 defined by the inner diameter of the lower extraction pipe to the cross-sectional area S2 defined by the inner diameter of the lower extraction pipe is 0 . 25-1.0
(See FIG. 1).

Further, the above-mentioned wet separation apparatus of the present invention is provided in a plurality of stages, and the lower extraction pipe of the upper wet separation apparatus is connected to the inlet of the liquid to be treated of the lower wet separation apparatus.
The same ratio as the liquid from the upper extraction pipe (immersion pipe) of the separation device
It can be configured to collect heavy objects to be processed (see FIG. 5). The upper and wet fractionation apparatus of the present invention
The amount of liquid discharged to the side is larger than the amount of liquid discharged downward.
A normal liquid cyclone is provided in multiple stages, and the lower extraction pipe of the upper wet separation device is connected to the liquid inlet of the lower liquid cyclone to be treated , and the upper extraction tube of the upper wet separation device
(Immersion tube) from the object to be processed with a specific gravity similar to that of the liquid
And the upper extraction pipe of the lower hydrocyclone (immersion
An object to be processed mainly having a lower specific gravity than the liquid can be recovered from the tube (see FIG. 6). These wet separation devices are used as a waste plastic separation device having an improved PS recovery rate by supplying a mixed waste plastic fragment containing liquid containing at least polystyrene (PS) to an inlet of a liquid to be treated. be able to. The apparatus of the present invention is applicable to solid-liquid separation and liquid-liquid (oil-water) separation other than waste plastic separation.

The cyclone is basically for refining and recovering a supplied gas or liquid containing heavy fine particles. Therefore, the lower exhaust or drainage amount from which foreign matter is discharged has been used only under extremely small conditions compared to the upper exhaust or drainage amount. The present inventors have repeatedly studied and studied to apply this cyclone technology to waste plastic separation. Specifically, the main material constituting the waste plastic is P, which has a higher specific gravity than water.
VC, PET (heavy material), PS with a specific gravity slightly larger than water
(Medium heavy material), PE and PP (light material), which have smaller specific gravity than water. Studying the separation by liquid cyclone using a mixture of plastic particles (PVC, PS, PE) with three different specific gravities. As a result, new findings as shown in FIG. 7 were obtained.

FIG. 7 summarizes the state of separation of each sample in the hydrocyclone using the flow shown in FIG. 10 in the relationship between the specific gravity difference between liquid and particles (liquid density-plastic density) △ ρ. . In FIG. 7, the solid line represents the conventional operation method of the hydrocyclone, that is, the supply water amount Q = 700 L
/ Min under normal operating conditions (upper drainage rate Ro = 0.80) where 560 L / min of water is drained from above.
This is the case where the treatment was performed under the operating condition of draining excessively 100 L / min downward (upper drainage rate Ro = 2/7 = 0.29). The plastic concentration Cp in the feed water is 3.0 kg.
/ M ³ and the material of the plastic particles is PVC
(Heavy material), PS (medium heavy material), PE (light material). In FIG. 7, the specific gravity difference Δρ = −0.22
5 (PVC), -0.028 (PS), 0.095 (P
E) is a case where city water is used, and the specific gravity difference Δρ = −0.
0023 (PS) is the case where 3.0 w / v% saline was used, and the specific gravity difference Δρ = −0.175 (PVC), 0.0
27 (PS) is the case where 6.8 w / v% saline was used, and the specific gravity difference Δρ = −0.125 (PVC), 0.072
(PS) is the case where 13.3 w / v% saline was used.

As can be seen from FIG. 7, under normal operating conditions (upper drainage rate Ro = 0.80), PE (light material) is discharged 100% upward, PVC (heavy material) is discharged 100% downward, PS (medium heavy substances) is discharged about 20% upward. On the other hand, on the other hand, excess discharge is downward (upward drainage rate Ro =
0.29), a sample having a specific gravity near the liquid specific gravity (specific gravity difference Δρ is around 0) is discharged upward while maintaining an upper recovery rate ro approximately equal to the upper drainage rate Ro of the liquid, Most of the sediment and light materials have been discharged downward. That is, under the operating conditions of excessive downward discharge, although the amount recovered at the top does not increase, only the sample having a specific gravity similar to that of the liquid can be selectively recovered from above with high purity.

The result is that when a swirling flow is created like a cyclone and the liquid is extracted from the upper and lower central axes, the flow of the liquid near the central axis where the light matter gathers is increased or decreased according to the amount of the extracted water. This is because the movement is unidirectional. That is, as shown in FIG. 8, when the amount of drainage above the liquid cyclone 14 is large, the liquid supplied from the liquid inlet 16 to be processed forms a swirl flow, and the light substances collected near the central axis are generated by the reverse flow. By suction, the inside of the upper extraction pipe (immersion pipe) 18 moves upward. Further, as shown in FIG. 9, when there is a large amount of downward drainage from the hydrocyclone 14, the light materials collected near the central axis move downward to the lower extraction pipe 20 by being pulled by the downward discharge. 8 and 9, illustration of the right half of the hydrocyclone is omitted. The method and apparatus of the present invention, based on the above new findings,
The amount of liquid discharged below the device is made sufficiently larger than the amount of liquid discharged above the device,
An object to be treated (solid or liquid) having the same specific gravity as the liquid can be selectively recovered with high purity.

[0021]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an embodiment of the present invention will be described for the case where the wet separation apparatus of the present invention is a waste plastic separation apparatus, but the present invention is not limited to the separation of waste plastic. However, the present invention can be applied to other solid-liquid separation and liquid-liquid (oil-water) separation. 1 and 2 show a wet type sorting apparatus according to a first embodiment of the present invention. As an example, the present embodiment describes a pipe cross-sectional area of the upper extraction pipe (immersion pipe) and the lower extraction pipe so that the lower extraction liquid amount in the hydrocyclone is sufficiently larger than the upper extraction liquid amount. The ratio is adjusted. As shown in FIGS. 1 and 2, the main body 25 of the hydrocyclone 14 c includes a cylindrical portion 26 and a substantially inverted conical portion 28 connected to the lower end of the cylindrical portion 26. A liquid supply unit 30 having a liquid inlet 16c to be processed is provided in the main body 2.
An upper extraction pipe (immersion pipe) 18 c having an upper extraction outlet 32 whose tip projects from the upper surface of the main body 25 is provided at the upper part in the inside 5, and the lower end of the substantially inverted conical part 28 has a lower extraction pipe (dip). An outlet 34 is provided, and a lower extraction pipe 20c
Is connected. The liquid supply unit 30 having the liquid inlet 16c to be processed in a substantially tangential direction may be configured as shown in FIG. 3 in addition to the configuration shown in FIG.

As described above, the amount of liquid discharged below the hydrocyclone 14c must be sufficiently larger than the amount of liquid discharged above. Here, the upper extraction pipe (immersion pipe) 18c
Is 1 to 40%, preferably 10 to 30% of the amount of liquid supplied to the liquid inlet 16c.
When adjusting the amount of liquid discharged from the upper extraction pipe (immersion pipe) 18c and the amount of liquid extracted from the lower extraction pipe 20c at such a ratio, the upper extraction pipe (immersion pipe) 18c and / or Although it is conceivable to provide a mechanical flow control device such as a valve in the lower extraction pipe 20c, in the present embodiment, an apparatus for basically processing waste plastic having a particle size of 2 to 30 mm such as crushed waste plastic is considered. Therefore, no mechanical flow control device such as a valve is provided in the apparatus piping. Therefore, the amount of liquid to be withdrawn from the upper extraction pipe (immersion pipe) 18c and the lower extraction pipe 20c
The flow rate ratio to the amount of liquid withdrawn from the tube is defined by the cross-sectional area ratio of the two, that is, the cross-sectional area S1 defined by the inner diameter of the upper extraction pipe (immersion pipe) 18c and the inner diameter of the lower extraction pipe 20c. This is almost determined by the ratio to the sectional area S2, and a slight adjustment is made depending on the pipe resistance and the discharge position (height). Therefore, in FIG. 1, S1 / S2 is 0 . 2
It is assumed to be in the range of 5 to 1.0. If this condition is satisfied, there is no particular limitation on the device shape of the cylindrical portion 26, the substantially inverted conical portion 28, and the like, and a configuration in which the main body 25 is withdrawn downward from the lower side surface may be employed.

The above-described liquid cyclone of the present embodiment is applied to an apparatus having a structure as shown in FIG. 4 and has three or more different specific gravities (a heavy substance having a specific gravity greater than that of a liquid, and a specific gravity in the vicinity of the liquid specific gravity. When it is desired to selectively recover medium-heavy substances having a specific gravity near the liquid specific gravity from separated medium-heavy substances and light substances having a lower specific gravity than the liquid), for example, heavy substances (PVC, PET) ), A case where PS is selectively recovered from a mixture of crushed pieces of medium and heavy substances (PS) and light substances (PE and PP). As shown in FIG. 4, the separation target and city water (or a saline solution, etc.) are charged into a processing target liquid tank 36, and the processing target liquid in the tank 36 is pumped by a pump 12.
To supply to the liquid inlet 16c of the liquid cyclone 14c. In the liquid cyclone 14c, the supplied liquid forms a swirling flow, and heavy substances (for example, PV
C, PET) on the outside, light materials (eg, PE, PP)
Is in the center (near the central axis), medium-heavy materials (for example, PS)
Gather in the middle of each. Here, the amount of liquid to be withdrawn from the upper withdrawal pipe (immersion pipe) 18c is determined by the inflow port 1 for the liquid to be treated.
By making the amount of liquid extracted from the lower extraction pipe 20c sufficiently large as 1 to 30% of the amount of liquid supplied to 6c, most of the light substances (for example, PE, PP) collected near the central axis. Is being pulled by the downward emissions, causing heavy matter (eg, P
VC and PET) are discharged from the lower extraction pipe 20c, and medium and heavy substances (for example, PS) are discharged from the upper extraction pipe (immersion pipe) 18c with high purity.
That is, by lowering the upper drainage rate, the upper recovery rate of light materials (for example, PE and PP) can be increased.
Since the recovery rate is lower than the reduction in the recovery rate of S), the purity of the medium and heavy substances (for example, PS) recovered from the upper part is improved. The liquid containing the medium heavy substance and the light substance is introduced into the solid-liquid separator 22, and is separated into a solid and a liquid, and the medium heavy substance and the light substance are recovered. Numeral 24 denotes a solid-liquid separator for the lower discharge, and the liquid separated by the solid-liquid separators 22 and 24 is circulated to the liquid tank 36 to be treated.

FIG. 5 shows a wet separation apparatus according to a second embodiment of the present invention. This embodiment is the first embodiment.
A plurality of liquid cyclones in the form are multi-stage (in FIG. 5,
In one example, the lower extraction pipe of the upper liquid cyclone is connected to the inlet of the liquid to be treated of the lower liquid cyclone to constitute a waste plastic sorting apparatus. Each numerical value in FIG. 5 indicates the flow rate (unit: L) in each pipe.
/ Min). As shown in FIG. 5, a pre-crushed mixed waste plastic fragment (for example, PP, PE, PS,
A liquid containing mixed waste plastic crushed pieces comprising PVC, PET) and city water (or saline) is charged into a plastic-containing liquid tank 10, and the mixed waste plastic crushed piece-containing liquid in the tank 10 is subjected to liquid cyclone by a pump 12. 14c
Is supplied to the liquid inlet 16c. Liquid cyclone 1
In 4c, as described above, the amount of liquid discharged from the lower discharge pipe 20c is sufficiently larger than the amount of liquid discharged from the upper discharge pipe (immersion pipe) 18c. The heavy matter (in this case, PS) is selectively discharged from the upper extraction pipe (immersion pipe) 18c, and the lower part of the light matter (in this case, PP or PE) and the heavy substance (in this case, from the lower extraction pipe 20c). , PV
C, PET) and the unrecovered portion of medium heavy substances (PS) are discharged. The liquid discharged from the lower withdrawal pipe 20c is supplied to the liquid inlet 16d of the liquid cyclone 14d. Also in the liquid cyclone 14d, the amount of liquid discharged from the lower discharge pipe 20d is set to be sufficiently larger than the amount of liquid discharged from the upper discharge pipe (immersion pipe) 18d. Heavy matter (PS) is selectively discharged from the upper extraction pipe (dipping pipe) 18d. 38, 40 and 42 are solid-liquid separators. Thereby, the recovery rate of the medium-heavy substances (in this case, PS) can be further improved. In addition, since the flow rate of each pipe cannot be ensured, it is possible to increase the number of stages of the liquid cyclone which has been impossible in the past. In addition, 1
It is also possible to adjust the flow rate such as reducing the amount of liquid to be withdrawn from the upper extraction pipe (immersion pipe) of the stage, and to implement three or more stages in series. Other configurations and operations are the same as those in the first embodiment.

FIG. 6 shows a wet separation apparatus according to a third embodiment of the present invention. This embodiment is the first embodiment.
The liquid cyclone and the normal liquid cyclone in the form are provided in multiple stages (in FIG. 6, two stages as an example), and the lower extraction pipe of the upper liquid cyclone is connected to the liquid inlet of the lower liquid cyclone to be treated, It is configured as a waste plastic sorting device. Each numerical value in FIG. 6 is a flow rate (unit: L / min) in each pipe. As shown in FIG. 6, mixed waste plastic crushed pieces (for example, PP, P
E, PS, PVC, PET) and a mixed waste plastic crushed piece containing liquid consisting of city water (or saline solution) are charged into the plastic-containing liquid tank 10, and the mixed waste plastic crushed-piece-containing liquid in the tank 10 is pumped. The liquid 12 is supplied to the liquid inlet 16c of the liquid cyclone 14c. In the hydrocyclone 14c, as described above, the lower extraction pipe 20
Since the amount of liquid discharged from c is sufficiently larger than the amount of liquid discharged from the upper discharge pipe (immersion pipe) 18c, a part of light substances and a medium heavy substance (PS in this case) are selectively provided. It is discharged from the upper extraction pipe (immersion pipe) 18c, and the remaining light substances (in this case, PP and PE), heavy substances (in this case, PVC and PET) and medium heavy substances (PS) are discharged from the lower extraction pipe 20c. Uncollected portion is discharged. The liquid discharged from the lower withdrawing pipe 20c is supplied to the liquid inlet 16e of the liquid cyclone 14e. In the liquid cyclone 14e, normal operating conditions, that is, the amount of liquid discharged from the upper extraction pipe (immersion pipe) 18e is set to be sufficiently larger than the amount of liquid discharged from the lower extraction pipe 20e. All of the material (PP, PE) and a part of the medium heavy material (PS) are discharged from the upper extraction pipe (immersion pipe) 18e. 38, 40 and 42 are solid-liquid separators. As a result, the recovery rate of medium and heavy substances (in this case, PS) can be further improved, and the recovery rate of suitable oily materials (in this case, PP, PE, and PS) can be improved. PET is difficult to recover as oil,
Since PVC contains chlorine, there is a risk of generation of dioxin and corrosion of a combustion device, and both are unsuitable for oiling. In addition, since the flow rate of each pipe cannot be ensured, it is possible to increase the number of stages of the liquid cyclone which has been impossible in the past. It is also possible to adjust the flow rate such as reducing the amount of liquid to be withdrawn from the upper withdrawal pipe (immersion pipe) in the first stage, and to implement three or more stages in series. Other configurations and operations are the same as those in the first embodiment.

[0026]

EXAMPLES Examples and comparative examples are shown below to further clarify the features of the present invention. Example 1 Separation of a plastic mixture composed of particles of PVC (heavy matter), PS (medium heavy matter) and PE (light matter) (particle size: 2 to 30 mm) using city water in the apparatus shown in FIG. The test was performed. The shape of the hydrocyclone (see Fig. 1)
Upper extraction pipe (immersion pipe) cross section S2: 2826 mm ² , lower extraction pipe cross section S2: 4416 mm ² , cylindrical part inner diameter: 300 mm,
Cylindrical part height: 650 mm, substantially inverted conical part height: 300 mm, upper extraction pipe (immersion pipe) length: 400 mm, liquid supply part hole diameter: 6
5 mm. Note that S1 / S2 = 0.64. The liquid cyclone is supplied at 700 L / min and the upper drainage rate is 29%.
(200 L / min of upper drainage, 500 L / min of lower drainage). As for each of the supplied samples, the PVC upper recovery rate was 0 wt%, the PS upper recovery rate was 15.1 wt%, and the PE upper recovery rate was 7.6 wt%. became. In the case where three samples were mixed in equal amounts, the PS purity of the upper recovered product was 66.5 wt%.
A sample containing a large amount of PS having a specific gravity close to that of water could be recovered. This is because, by lowering the upper drainage rate, the upper recovery rate of PE was lower than the lowering of the recovery rate of PS, so that the PS purity of the upper recovery product was improved. As a result, it was found that the sample having a specific gravity near the liquid specific gravity can be used as an apparatus for selectively recovering the sample with high purity.

Comparative Example 1 In the apparatus shown in FIG.
A fractionation test was performed on a plastic mixture composed of (heavy matter), PS (medium heavy matter) and PE (light matter) particles (particle diameter: 2 to 30 mm). The basic shape of the hydrocyclone is the same as that of Example 1 except for the cross-sectional area S1 of the upper extraction pipe (immersion pipe) and the cross-sectional area S2 of the lower extraction pipe. The liquid cyclone is supplied at a supply water volume of 700 L / min and an upper drainage rate of 86% (upper drainage 600 L
/ Min, 100 L / min of downward drainage), and for each sample supplied, the upper recovery rate of PVC was 0 wt%,
PS upper recovery rate 23.4wt%, PE upper recovery rate 100wt
%. That is, the entire amount of PE and a part of PS were collected as the upper collection, and the whole amount of PVC and most of PS were collected as the lower collection. When three samples were mixed in equal amounts, the PS purity of the upper recovered product was 19.0 wt%. Therefore, in the case of Comparative Example 1, as a device for recovering a sample having a specific gravity close to the specific gravity of the liquid, the PS purity of the upper recovered material was low and was unsuitable. In addition, as a device for recovering oily material (fuel material), the rate of upward recovery of PS was low and was not suitable. Table 1 shows the results of Example 1 and Comparative Example 1 of the present invention.

[0028]

[Table 1]

Example 2 In the apparatus shown in FIG. 4, PVC (heavy substances), P (heavy substance), P
S (medium heavy material) and PE (light material) particles (particle size 2-3)
0 mm). The shape of the hydrocyclone is the same as in the first embodiment. Liquid cyclone is supplied at 700 L / min of supply water and upper drainage rate 2
9% (upper drainage 200L / min, lower drainage 500L / min)
, The PV of each sample supplied was
C upper recovery rate 0.3wt%, PS upper recovery rate 31.3wt
%, And a PE upper recovery rate of 2.4 wt%. When three samples were mixed in equal amounts, the PS purity of the upper recovered material was 92.1 wt%.
%, Indicating that it can be used as an apparatus for recovering PS (those having an intermediate specific gravity among the three types) with a purity of 90% or more from the three types of plastics. Table 2 shows the results of Example 2 of the present invention.

[0030]

[Table 2]

Example 3 In the apparatus shown in FIG. 6, using city water, a plastic composed of particles of PVC (heavy matter), PS (medium heavy matter) and PE (light matter) (particle diameter: 2 to 30 mm) The mixture was subjected to a fractionation test. The shape of the first (upper) liquid cyclone is the same as in Example 1, and the shape of the second (lower) liquid cyclone is the same as Comparative Example 1. The first stage liquid cyclone is supplied with a supply water volume of 700 L / min and an upper drainage rate of 29%.
(Upper drainage 200L / min, lower drainage 500L / min)
(Upper drainage 400 L / min, lower drainage 100 L / min), the results were as shown in Table 3. In the third embodiment, the multistage operation which cannot be performed by the normal cyclone is possible. Also, from the results in Table 3, the PS recovery capability of the multistage device indicates that the normal cyclone alone having an upper drainage rate of 86% is used. It was found to be about 1.5 times higher than the case where the treatment was performed. In addition, it was found that the recovery rate of the material suitable for fuel combining PE and PS was also improved. Furthermore, in the apparatus shown in FIG. 6, the lower discharge (a part of the heavy and medium heavy substances) of the second-stage hydrocyclone is not collected,
If a batch processing method is used to return the sample to the tank again, 90% of PS will be obtained within 10 minutes after the sample is put into the first stage cyclone.
Can be recovered from a calculation based on the upper recovery rate. On the other hand, with a normal cyclone having an upper drainage rate of 86%, it took 14 minutes to recover 90% of PS by the same batch processing method. Therefore, the type of the third embodiment is a waste plastic sorting device (a device for collecting fuel-compatible material).
Was found to be more suitable.

[0032]

[Table 3]

[0033]

As described above, the present invention has the following effects. (1) Wet fractionation (for example, liquid cyclone) in which the object to be treated (object to be treated) is separated by the difference in specific gravity between the object to be treated (object to be treated) and the liquid by utilizing the centrifugal force of the swirling flow of the liquid to be treated. In the above, by increasing the amount of liquid discharged below the apparatus compared to the amount of liquid discharged above the apparatus, the processing target (processing object) having a wide specific gravity distribution centering on specific gravity 1 A fraction containing a large amount of a specific object (solid or liquid) having a specific gravity similar to that of a liquid can be selectively recovered from above with high purity. (2) In wet separation using a hydrocyclone, by increasing the flow rate ratio of the liquid discharged above and below the hydrocyclone to the lower side, a large amount of materials to be processed having a specific gravity near the specific gravity of the liquid is included. When the present invention is used for separating waste plastics, waste plastic mixtures (main materials: PP, PE, PS, PVC, P
From ET), PS having a specific gravity slightly larger than 1 can be selectively recovered upward with high purity. (3) When the particle size of the object to be treated is large, such as waste plastic, it is necessary to increase the flow rate of each pipe to prevent blockage of the pipe. Conventionally , the amount of liquid discharged upward is reduced.
Although the liquid cyclone could not be connected in series on the downstream side (lower stage) of the normal liquid cyclone that is larger than the discharged liquid amount , the present invention increases the flow rate of the liquid discharged below the liquid cyclone. Therefore, the number of stages can be increased by connecting the liquid cyclones in series on the downstream side (lower stage) of the hydrocyclones. (4) When the present invention is used for separation of waste plastics by providing the hydrocyclone of the present invention in a plurality of stages, a waste plastic mixture (main materials: PP, PE, P
S, PVC, PET) can further improve the recovery rate of PS. (5) On the downstream side (lower stage) of the hydrocyclone of the present invention ,
The amount of liquid discharged upward is smaller than the amount of liquid discharged downward.
When the present invention is used to separate waste plastics by incorporating a large normal hydrocyclone, waste plastic mixtures (main materials: PP, PE, PS, PVC, P
ET) to material suitable for fuel (oil suitable material: PP, PE, PS)
Can be efficiently collected.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing a wet sorting apparatus according to a first embodiment of the present invention.

FIG. 2 is a diagram showing an example of a cross section taken along line AA of the apparatus shown in FIG.

FIG. 3 is a diagram showing another example of a cross section taken along line AA of the apparatus shown in FIG.

FIG. 4 is a schematic configuration diagram showing a basic flow for performing the wet separation method of the present invention.

FIG. 5 is a schematic configuration diagram illustrating a wet type sorting apparatus according to a second embodiment of the present invention.

FIG. 6 is a schematic configuration diagram illustrating a wet type sorting apparatus according to a third embodiment of the present invention.

FIG. 7 is a graph showing a relationship between a specific gravity difference between a liquid and a plastic and an upper recovery rate of various plastics in a waste plastic separation apparatus using two types of liquid cyclones having an upper drainage rate.

FIG. 8 is a conceptual diagram showing the behavior of particles of each specific gravity in a normal hydrocyclone with a large amount of upward drainage.

FIG. 9 is a conceptual diagram showing the behavior of particles of each specific gravity in a hydrocyclone with a large amount of downward drainage.

FIG. 10 is a schematic diagram showing a general flow when waste plastic is separated using a conventional hydrocyclone.

FIG. 11 is a conceptual diagram when a plurality of conventional hydrocyclones are installed in multiple stages.

[Explanation of symbols]

Reference Signs List 10 Plastic-containing liquid tank 12 Pump 14, 14a, 14b, 14c, 14d, 14e Liquid cyclone 16, 16a, 16b, 16c, 16d, 16e Liquid to be treated inlet 18, 18a, 18b, 18c, 18d, 18e Withdrawing from above Pipes (immersion pipes) 20, 20a, 20b, 20c, 20d, 20e Lower extraction pipes 22, 24, 38, 40, 42 Solid-liquid separator 25 Main body 26 Cylindrical part 28 Substantially inverted conical part 30 Liquid supply part 32 Upper extraction Outlet 34 Lower extraction outlet 36 Liquid tank to be treated S1 Cross-sectional area of upper extraction pipe (immersion pipe) S2 Cross-sectional area of lower extraction pipe

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-51-120466 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) B03B 5/00-5/74 B04C 5 / 00-11/00

Claims (10)

(57) [Claims] An apparatus that separates an object to be processed upward or downward by using a centrifugal force generated by a swirling flow of the liquid to be processed to separate the object to be processed upward or downward by using a specific gravity difference between the liquid and the liquid to be processed. When sorting the objects to be processed, the amount of liquid discharged below the apparatus is made larger than the amount of liquid discharged above the apparatus, so that the object having a specific gravity similar to that of the liquid is lifted above the apparatus. A wet separation method comprising recovering from a liquid discharged to a tank. 2. The wet separation method according to claim 1, wherein the amount of the liquid discharged above the apparatus is 1 to 40% of the amount of the liquid to be processed supplied to the apparatus. 3. The method according to claim 1, wherein the apparatus is a hydrocyclone. 4. The wet fractionation method according to claim 1, wherein the liquid to be treated is a liquid containing mixed waste plastic fragments containing polystyrene. 5. When separating plastics having a specific gravity similar to that of water by using a multistage liquid cyclone provided in a plurality of units in series, the same liquid as the water is supplied to a liquid inlet to be treated of the uppermost liquid cyclone. By supplying a liquid containing mixed waste plastic crushed pieces containing plastic having a specific gravity of, the amount of liquid discharged below the hydrocyclone is made larger than the amount of liquid discharged above, so that the specific gravity of water is about the same. While recovering the plastic from the liquid discharged upward, the liquid discharged downward is supplied to the liquid inlet of the lower liquid cyclone to be treated, and the same operation as the upper liquid cyclone is repeated in the lower liquid cyclone. The wet separation method is characterized by recovering plastic having the same specific gravity as water from the liquid discharged upward, and improving the recovery rate of plastic having the same specific gravity as water. Law. 6. A liquid flow to be treated in the uppermost liquid cyclone when a plastic having a specific gravity similar to that of water is separated together with a plastic having a specific gravity smaller than that of water using a multistage liquid cyclone provided in plurality in series. At the inlet, a liquid containing mixed waste plastic crushed pieces containing a plastic having the same specific gravity as water and a plastic having a lower specific gravity than water is supplied, and the amount of liquid discharged below the hydrocyclone is increased to the amount of liquid discharged above. By increasing the size, plastic having a specific gravity similar to that of water is mainly recovered from the liquid discharged upward, and the liquid discharged downward is supplied to the inlet of the liquid to be treated of the lower liquid cyclone. In the liquid cyclone, the amount of liquid discharged upward is larger than the amount of liquid discharged downward, so that the specific gravity of water is lower than that of water. A wet fractionation method comprising collecting tics from a liquid discharged upward to improve the total recovery rate of plastic having a specific gravity similar to that of water and plastic having a specific gravity smaller than that of water. 7. An upper discharge pipe having a tangential liquid inlet in the upper part of the main body and an upper discharge pipe provided in the upper part of the main body such that a tip projects from the upper surface of the main body to form an upper discharge outlet. ,
Has a lower extraction port in the lower body, the hydrocyclone lower extraction pipe is connected to the lower extraction port, the liquid cycle
To the amount of liquid discharged upward
In comparison with the liquid, the object to be treated has a specific gravity
The ratio S1 / S2 of the cross-sectional area S1 defined by the inner diameter of the upper withdrawal pipe to the cross-sectional area S2 defined by the inner diameter of the lower withdrawal pipe, so that the liquid is recovered from the liquid discharged toward the lower side, is obtained. 0.25
The wet type separation device, wherein the range is from 1.0 to 1.0 . 8. A wet separation apparatus according to claim 7, which is provided in a plurality of stages and a lower extraction pipe of an upper wet separation apparatus is connected to an inlet of a liquid to be treated of a lower wet separation apparatus. Classification
An object to be treated with a specific gravity similar to that of the liquid
Wet sorter designed to collect . 9. An apparatus according to claim 7, wherein said apparatus is discharged upwardly.
A liquid cyclone in which the amount of liquid discharged is larger than the amount of liquid discharged downward is provided in multiple stages, and the lower extraction pipe of the upper wet separation device is connected to the liquid inlet of the lower liquid cyclone to be treated. To the upper part of the upper wet separation device.
Collect an object with a specific gravity similar to that of the
Lower specific gravity than liquid mainly from upper extraction pipe of cron
Wet sorter for collecting objects to be treated . 10. The waste plastic separating apparatus according to claim 7, wherein a liquid containing mixed waste plastic fragments containing at least polystyrene is caused to flow into the inflow port of the liquid to be treated. Wet sorter.