KR100939805B1 - Waste Separation method - Google Patents

Abstract

In the present invention, the plastic waste recycling business uses the dehydration, specific gravity, and wind power to separate the synthetic resin according to the purpose from the sludge of the last disposal stage, which is treated as a simple waste. It provides a method of separating wastes that significantly lowers the cost and also enables the reuse of the selected synthetic resins to create new added value.

To this end, the present invention, in the waste separation method for separating the necessary synthetic resin from the remaining sludge after the synthetic resin is separated from the waste synthetic resin according to the purpose of use,

Centrifuging the sludge to separate the synthetic resin and the soil;

Pure water is stored in the sedimentation tank, the first specific gravity separation step of separating the heavy synthetic resin only by the specific gravity difference is supplied with the synthetic resin separated from the one-dimensional core separation step;

A second centrifugation step of dehydrating water by centrifuging the synthetic resin separated by the first specific gravity separation step and separating only the heavy synthetic resin again;

A second specific gravity separation step in which water containing salt is stored in the precipitation tank, and the synthetic resin separated from the second centrifugation step is supplied to separate only the light synthetic resin by the specific gravity difference;

And a third centrifugal separation step of dehydrating water by centrifuging the synthetic resin separated by the second specific gravity separation step and separating only the lightweight synthetic resin again.

Description

Waste Separation Method

1 is a view showing the structure of a waste separation apparatus according to the present invention.

2 is a flow chart showing a waste separation method.

<Brief description of the main parts of the drawing>

10 Conveyor 20 Primary Centrifuge

30: primary transfer pipe 40: primary hydrometer

50: secondary centrifuge 60: secondary feed pipe

70: secondary centrifuge 80: third centrifuge

90: 3rd transfer pipe 100,110: hopper

120: trimmer

The present invention relates to a waste separation method, and more particularly, to a waste separation method that enables separation of crushed waste synthetic resins from resins that meet the purpose of use by difference in dehydration and specific gravity, and by wind power.

In general, synthetic resins such as PE, PP, PS, PET, and ABS do not rot for a long time, which is a major cause of environmental pollution.

Therefore, by collecting and sorting the synthetic resin after use, and then crushed and recycled, it minimizes environmental pollution and reduces the social cost for it.

However, even after the recycled synthetic resin is recycled, sludge remains in a state in which the remaining synthetic resin waste and the like are mixed, which is discarded as it cannot be treated separately.

As a result, there is a problem that environmental pollution remains, as well as the recycling rate itself is greatly reduced.

That is, it is preferable to recycle all of the waste synthetic resins up to the last stage, but it is very difficult to recycle all of them.

Therefore, the present invention was devised to solve the conventional problems as described above, by separating the synthetic resin meeting the purpose of use by the difference in dehydration and specific gravity and wind power from the sludge of the last disposal step to recycle to the last step It is an object of the present invention to provide a waste separation method which greatly reduces the possibility of environmental pollution by the use of the same.

Waste separation method according to the present invention as described above
In the waste separation method for separating the required synthetic resin from the remaining sludge after separating the synthetic resin suitable for the purpose of use from the waste synthetic resin,
Centrifuging the sludge to separate the synthetic resin and the soil;
Pure water is stored in the sedimentation tank, the first specific gravity separation step of separating the heavy synthetic resin only by the specific gravity difference is supplied with the synthetic resin separated from the one-dimensional core separation step;
A second centrifugation step of dehydrating water by centrifuging the synthetic resin separated by the first specific gravity separation step and separating only the heavy synthetic resin again;
A second specific gravity separation step in which water containing salt is stored in the precipitation tank, and the synthetic resin separated from the second centrifugation step is supplied to separate only the light synthetic resin by the specific gravity difference;
And a third centrifugal separation step of dehydrating water by centrifuging the synthetic resin separated by the second specific gravity separation step and separating only the lightweight synthetic resin again.

delete

delete

delete

delete

delete

delete

The present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, various waste synthetic resins are pulverized and mixed, and waste is mixed with waste plastics such as PE, PP, PS, PET, and ABS, as well as soil and iron.

These sludges are loaded on the conveyor 10 and moved to the primary centrifuge 20 to separate steel materials. For this purpose, magnets 11 are spaced apart from the surface of the conveyor 10 at an upper side of the conveyor 10. This is installed.

Therefore, iron sludge is separated by the magnetic force of the magnet 11 while the sludge is transported on the conveyor 10.

The sludge from which the iron is separated is transferred along the upwardly inclined conveyor 10 and introduced into the upper portion of the primary centrifuge 20, and the waste synthetic resin and the soil are separated by the primary centrifuge 20.

The first centrifugal separator 20 has a drum made of a mesh inside, and when the drum rotates, heavy soil is discharged to the outside of the drum through the net by centrifugal force and collected at the lower separator 21 to be discharged. The waste synthetic resin from which the soil is separated is discharged through the outlet 22 provided in the side portion.

At this time, since the wind is generated while the drum rotates, the waste synthetic resin is blown to the discharge port 22 by using the wind power and discharged.

As another method, a separate wind turbine may be installed inside the first centrifugal separator 20 to generate forced wind power, and the waste synthetic resin may be blown out toward the outlet 22.

The waste synthetic resin discharged through the discharge port 22 is conveyed to the upper side of the primary non-concentrator 40 through the upwardly inclined transfer pipe 30, and the transfer pipe 30 has a feed screw built in the longitudinal direction therein. In this case, the waste synthetic resin introduced through the inlet 31 is conveyed upward by the feed screw.

The waste synthetic resin transferred to the upper side from the inside of the conveying pipe 30 is introduced into the primary decanter 40 located below the outlet 32 through the outlet 32 on the upper side thereof. 40) by the heavy waste synthetic resin is filtered, the first specific gravity (40) is formed in the shape of a reservoir is a pure water is stored therein.
Therefore, when the waste synthetic resin is introduced into the inside through the upper portion of the first non-gravity machine 40, the heavy waste synthetic resin sinks to the bottom, and the light waste synthetic resin floats on the water surface.

delete

The light waste synthetic resin suspended on the water surface is separated separately by being discharged to the outside through the separating opening 41 provided at the upper portion of the primary non-gravitizer 40, and the heavy waste synthetic resin is formed at the lower portion of the primary non-gravitizer 40. It is conveyed to the secondary centrifuge 50 through the outlet 42.
The inside of the discharge port 42, the feed screw is built, it is transferred upward along the upwardly inclined discharge port 42 and then introduced into the interior from the upper side of the secondary centrifuge (50).

delete

The structure of the secondary centrifuge (50) is the same as that of the primary centrifuge (20), and while the drum inside rotates to dehydrate water accumulated in the waste synthetic resin, heavy waste synthetic resin and light waste synthetic resin by wind power. Selected heavy waste synthetic resin is discharged to the outlet 52 of the side, the light waste synthetic resin is separated separately by discharging through the lower separating port (51).

The heavy waste synthetic resin discharged through the discharge port 52 flows into the inlet 61 of the upwardly inclined secondary transfer pipe 60 and is transferred to the outlet 62 of the upper side, and the primary transfer pipe 30 and Equally there is a built-in feed screw.

The waste synthetic resin transferred through the secondary conveying pipe 60 is introduced into the upper portion of the secondary condenser 70, and the secondary condenser 70 is configured almost the same as the primary condenser 40. The water containing salt is stored inside.

The reason the salt is contained is to control the specific gravity by adjusting the concentration of salt to separate only waste synthetic resins that meet the purpose of use by specific gravity.

The waste synthetic resin that has sunk to the lower portion of the secondary non-strainer 70 is discharged to the outside through a separate separator 71 on the lower side and separated separately. It is introduced into the third centrifuge 80 through the outlet 72.
Since the conveying screw is also built in the outlet 72, it is conveyed upward along the upwardly inclined outlet 72 and then introduced into the upper portion of the tertiary centrifuge 80.
The tertiary centrifuge 80 is also configured in the same manner as the primary and secondary centrifuges 20 and 50, and removes the moisture of the waste synthetic resin and at the same time the heavy waste synthetic resin by the wind through the lower separator 81 Separated by discharging to the outside, the light waste synthetic resin is conveyed to the upper side of the primary hopper 100 through the third feed pipe 90 inclined upward through the outlet 82 of the side.

delete

Similarly, the tertiary conveying pipe 90 is configured in the same manner as the primary and secondary conveying pipes 30 and 60, and the waste synthetic resin conveyed by the tertiary conveying pipe 90 is divided by the size through the trimmer 120. The small sized waste synthetic resin is contained in the primary hopper 100, and the large sized waste synthetic resin is contained in the secondary hopper 110.

The trimmer 120 is formed of a cylindrical body having a plurality of holes of a predetermined size, and has a structure to distinguish the waste synthetic resin by size.

Therefore, the primary hopper 100 and the secondary hopper 110 is to contain the separated waste synthetic resin product that is used in the final separation.

In the present invention, it is possible to form a relatively heavy waste synthetic resin such as ABS and PS through this separation process.

Each of the components described above is configured such that the feed pipe and the outlet are inclined upward so that the waste synthetic resin is injected into the upper part of the neighboring components so that each of these components can be disposed on a plane without height.
That is, the conveyor 10, the primary feed pipe 30, the outlet 42 of the primary non-gravity machine 40, the secondary feed pipe 60, the outlet 72 of the secondary non-gravity machine 70, 3 The primary centrifuge 20, the primary centrifuge 40, the secondary centrifuge 50, the secondary centrifuge 70, the tertiary centrifuge 80, and the hopper by the primary feed pipe 90 Since 100 and 110 may be located on the same line, that is, on the floor, there is no difference in height between the respective parts, so that a large facility for overcoming the height difference is not required, thereby greatly reducing the cost and space of installation.

As described above, the present invention is to reduce the possibility of environmental pollution by separating the synthetic resin suitable for the purpose of use by the difference in dehydration and specific gravity and wind power from the sludge of the last disposal step to recycle to the last step. It also has the effect of creating new added value by reusing selected plastics.

Claims (3)

In the waste separation method for separating the required synthetic resin from the remaining sludge after separating the synthetic resin suitable for the purpose of use from the waste synthetic resin, Centrifuging the sludge to separate the synthetic resin and the soil; Pure water is stored in the sedimentation tank, the first specific gravity separation step of separating the heavy synthetic resin only by the specific gravity difference is supplied with the synthetic resin separated from the one-dimensional core separation step; A second centrifugation step of dehydrating water by centrifuging the synthetic resin separated by the first specific gravity separation step and separating only the heavy synthetic resin again; A second specific gravity separation step in which water containing salt is stored in the precipitation tank, and the synthetic resin separated from the second centrifugation step is supplied to separate only the light synthetic resin by the specific gravity difference; And a third centrifugal separation step of dehydrating water by centrifuging the synthetic resin separated by the second specific gravity separation step and separating only the light weight synthetic resin again. The waste separation method according to claim 1, wherein the first centrifugal separation step comprises separating the iron from the sludge by a magnet. delete

Images