KR20200020055A - Waste Separator - Google Patents

Abstract

The present invention relates to a waste separating apparatus, which comprises: an input unit (10) provided at one side of an upper portion thereof to introduce waste thereinto; a cyclone unit (20) having the input unit (10) formed at an upper portion thereof, and centrifugally separating the introduced waste; a cover unit (30) provided on the upper portion of the cyclone unit (20) to seal a cyclone; a discharge unit (40) provided at the center of the cover unit (30), and discharging foreign substances separated from water; a collision unit (50) provided at one side of the cyclone unit (20), and having the introduced waste to collide therewith for separation; and an aggregate discharge unit (70) connected to the cyclone unit (20), and discharging aggregate from which the separated waste is removed. According to the present invention, waste is centrifuged by the cyclone unit and collides with the collision unit having an unevenness regenerated even in case of abrasion, thereby separating various contaminants attached to a surface of the waste. Therefore, a construction waste collides with the collision unit having the unevenness to more certainly separate foreign matters and concrete residues interfering with utilization of recycled aggregate.

Description

        Wet Waste Separator {Waste Separator}

  The present invention relates to a device for removing contaminated soil or foreign matter adhering to fine aggregates of crushed building waste, and specifically, to remove soil oil and heavy metals of contaminated soil to produce high-quality soil, or to construction waste. The present invention relates to a wet waste separation device capable of producing high quality recycled aggregates by separating various mixed matters and concrete residues.

In the process of reconstruction and extension of buildings, especially large buildings such as apartments, reconstruction and redevelopment, a large amount of construction wastes are generated. In such construction wastes, not only waste concrete but also various foreign substances are mixed. In addition, since contaminated soil contains oily residues, heavy metals, and the like, it is essential to remove various foreign matters and contaminants in order to produce high quality recycled aggregates and high quality soils suitable for soil restoration.

The main object of the present invention is to provide a waste separation apparatus for more reliably removing foreign substances and contaminated soil mixed in construction wastes and producing high-quality recycled aggregates in manufacturing recycled aggregates manufactured using construction wastes. will be.

Waste separation apparatus according to the present invention for achieving the object as described above, is provided on one side of the top, the input portion for inputting the construction waste and water into the interior, centrifugal separation of the construction waste and water introduced into the input portion Cylindrical portion and inclined portion which is a cyclone portion, a cover portion which is provided on the cyclone portion and the sealing function, an upper side vertical discharge portion through which fine waste particles and water escape, and is provided inside the cyclone portion. In addition, the incoming waste is rotated, colliding to separate the waste by collision, and the aggregate discharge portion connected to the lower end of the inclined portion and discharges the circulating aggregate from which the foreign matter is removed.

The impingement part is made of a wear-resistant material and is formed with an irregular shape on the outer circumferential surface.

A space portion is formed inside the impact portion, and thus continuously forms an uneven shape even when the impact portion is worn out.

A plurality of the space parts are formed to be offset from each other at regular intervals in the collision part.

The impingement part is formed on the upper fixing part formed under the cover part, the inner peripheral surfaces of the cylindrical part and the inclined part of the cyclone part, and is easy to replace when worn.

According to the wet waste separator of the present invention as described above, the wet cyclone is provided with a collision part in which a protrusion is formed. Building wastes forced by a pump or the like in the tangential direction of the cylinder with the water collide with the protrusions inside the cyclone and are turned down by gravity, ensuring that the wastes such as foreign substances and concrete pastes, which hinder the utilization of the circulating aggregate, are prevented. Provides a separable effect.

1 is a front sectional view showing a preferred embodiment of a waste separation apparatus according to the present invention.
Figure 2 is a cross-sectional plan view showing a preferred embodiment of the waste separation apparatus according to the present invention.
Figure 3 is a partial cross-sectional view showing a collision portion constituting the waste separation apparatus according to the present invention.
Figure 4 is an enlarged view showing a fixing portion constituting the waste separation apparatus according to the present invention.
Figure 5 is a partial cross-sectional view showing the wear and automatic regeneration state of the impact portion constituting the waste separation apparatus according to the present invention.

Hereinafter, a waste separator according to the present invention will be described with reference to the drawings.

1 is a front sectional view showing a preferred embodiment of the waste separation apparatus according to the present invention, FIG. 2 is a plan sectional view showing a preferred embodiment of the waste separation apparatus according to the present invention, and FIG. A partial cross-sectional view showing a collision part constituting a waste separating apparatus according to the invention is shown, FIG. 4 shows a fixing portion constituting the waste separating apparatus according to the present invention, and FIG. 5 constitutes a waste separating apparatus according to the present invention. A partial cross-sectional view showing the wear of the impact portion and the state of automatic regeneration is shown.

As shown in these figures, the waste separation apparatus of the present invention, which is provided on one side of the upper portion and the input unit 10 for injecting construction waste and water into the inside, and the input unit 10 is formed on the upper portion of the inlet The cover portion 30 of the upper seal is provided with a cyclone portion 20 for separating the waste, and the discharge portion 40 is provided on the cyclone portion 20 and the discharged portion 40 through which fine separated waste and water are drained. And, provided on one side of the cyclone portion 20, the impact portion 50 is separated by the incoming waste collide, and the aggregate is connected to the cyclone portion 20 and discharge the aggregate separated from the foreign matter and waste Discharge section 70 and the like.

The input portion 10 is made of a hollow cylindrical shape, the waste is injected with water. The inlet 10 is formed in a tangential direction on the upper side of the cyclone portion 20 to be described below, and injects waste into the cyclic direction along with water in the tangential direction.

The inlet 10 is connected to a pump (not shown) to inject water and construction waste into the cyclone unit 20. The connection structure of the input unit 10 and the motor and the pump is a general connection structure of a general wet cyclone apparatus and a detailed description thereof will be omitted.

The cyclone unit 20 is provided below the input unit 10. The body of the cyclone portion 20 is composed of a cylindrical portion 22 and a cone portion 24, the cylindrical portion 22 is formed of a hollow cylindrical shape, the building waste flowed in with the water tangential direction Let it rotate along. Conical portion 24 is formed below the cylindrical portion 22. The cone portion 24 has a hollow conical shape, the waste that rotates along the tangential direction in the cylindrical portion 22 is accelerated and rotated in the cone portion 24.

That is, the construction waste introduced into the cylindrical portion 22 and the cone portion 24 together with the water is rotated in a tangential direction along the wall surface, the aggregate having a high specific gravity while turning by centrifugal force to the protrusion 52 protruding from the wall surface. After completely separating foreign substances such as concrete paste on the surface, which causes turning friction and hinders the utilization of the circulating aggregate, it is collected in the lower part along the inside of the cylindrical part and the cone part and discharged by a belt conveyor (not shown). Light foreign matter and waste loaded in a weak whirlwind rising to the center of the cyclone gathers in the center of the 20 to form a rising swirling vortex. And the upward turning vortex is discharged to the discharge portion 40 to be described below.

The cover portion 30 is provided on the upper surface of the cyclone portion 20. The cover part 30 is formed in a disc shape to seal the upper surface of the cyclone part 20. A discharge part 40 is formed at the center of the cover part 30. The discharge portion 40 is formed in a hollow cylindrical shape is formed so that a portion protrudes below the cover portion (30). The discharge part 40 discharges waste, such as water, fine foreign matter, and separated concrete paste, which are taken up in the ascending swirling vortex to the outside.

The collision part 50 is installed in the inner peripheral surface of the cyclone part 20. The impingement part 50 is formed in a hollow cylindrical shape with a cross section, and is provided such that the protrusion part 52 protrudes in the inward direction of the cyclone part 20. When water and building waste are introduced into the input unit 10, the waste is accelerated by the turning force and collides with the protrusion 52 of the collision unit 50.

The collision part 50 is comprised from the protrusion part 52 which protrudes on the outer peripheral surface, and the space part 54 which forms a space inside.

The collision part 50 is formed to protrude along the inner circumferential surface of the cylindrical part 22 (see FIG. 2). A plurality of protrusions 52 are formed on the inner circumferential surface of the collision part 50. The protrusions 52 are formed in a hexahedral shape and a plurality of protrusions 52 are spaced apart at regular intervals along the inner circumferential surface of the collision part 50. Wastes that rotate with the water collide with the protrusions 52 to separate the contaminants attached to the wastes.

The space 54 is formed in the collision part 50. The space portion 54 has a hollow hexahedral shape, a plurality of spaces are formed at regular intervals. The space 54 is newly formed in order when the protrusion 52 is worn out by waste, and is exposed to the outside to form another protrusion 52 by the wall between the space 54.

Referring to FIG. 5, when the waste collides with the collision part 50 and is worn out, the first space part 54 ′ and the second space part (spaced apart from the impact part 50) are formed. 54 ″ is exposed to the outside. A first protrusion 52 'is formed between the first space 54' and the second space 54 '. Therefore, even when the collision part 50 is worn, the first protrusion part 52 'is formed between the 1st space part 54' and the 2nd space part 54 ", and the uneven shape of the collision part 50 is maintained. do.

The fixing part 60 is formed on the upper and lower parts of the collision part 50. The fixing part 60 is composed of an upper fixing part 62, a lower fixing part 64, a conical fixing part 68, and the like. The upper fixing portion 62 is formed to have an arc shape on the lower surface of the cover portion 30 to protrude. The upper surface of the collision part 50 is inserted into the upper fixing part 62 and fixed.

On the inner circumferential surface of the cyclone portion 20, a lower fixing part 64 having a "b" shape in cross section is formed along the inner circumferential surface. The lower surface of the collision part 50 is inserted into and fixed to the upper portion of the lower fixing part 64. That is, the upper and lower surfaces of the collision part 50 are inserted into and fixed to the upper fixing part 62 and the lower fixing part 64.

Fixing protrusions 68 are formed on the upper fixing part 62 and the lower fixing part 64. The fixing protrusion 66 protrudes to a certain height and is coupled to the insertion portion 58 recessed on the upper and lower surfaces of the collision part 50. The fixing protrusion 66 fixes the impact unit 50 more firmly. The fixing protrusions 66 may be provided in plural at regular intervals according to the thickness of the collision part 50.

The impact portion of the cone portion is fixed between the lower fixing portion 64 and the cone portion fixing portion 68.

The impact unit 50 may be made of various materials, such as cement, ceramics, special steel, depending on the type of waste.

The aggregate discharge portion 70 is installed below the cyclone portion 20. The aggregate discharge portion 70 is formed in a hollow cylindrical shape concave in the center serves to discharge the light foreign matter and waste removed from the cyclone portion 20, the discharged aggregate is a belt conveyor ( It moves to a predetermined place through a device such as a not shown) or a dewatering screen (not shown).

Hereinafter, the operation of the waste separation apparatus according to the present invention having the configuration as described above in detail.

First, building waste is introduced together with water into the input portion 10 installed in the tangential direction on the upper side of the cyclone portion 20. When the waste is input to the input unit 10, the waste is rotated along the tangential direction of the cyclone unit 20. As the waste rotates inside the cyclone unit 20, light waste is preferentially separated according to specific gravity by centrifugation.

In addition, the building waste introduced in the tangential direction of the cyclone portion 20 rotates along the collision part 50 installed in the cyclone portion 20. The building waste collides with the protrusion 52 formed to protrude in the inward direction of the collision part 50. The construction waste collides with the protrusion 52 so that the waste concrete lumps or contaminants attached to the surface of the construction waste are separated by collision and washing, and produce high-quality recycled aggregates.

When the waste collides with the protrusions 52 for a long time, the protrusions 52 wear out. When the protrusion 52 is worn by waste, the space 54 formed inside the collision part 50 is exposed to the outside. When the space 54 is exposed to the outside, a wall between the first space 54 'and the second space 54' serves as a new protrusion 52 '(see FIG. 5).

That is, the collision part 50 is gradually worn out by the impact of the waste is formed a plurality of hollow space portion 54 is formed therein, so that the wall between the space portion 54 is projected portion 52 To form.

Therefore, waste concrete collides with the impact part 50 and various contaminants attached to the waste are separated, and even when the protrusion part 52 is worn out, the protrusion part is formed by the space part 54 of the impact part 50. 52 is formed again.

The collision part 50 is fixed by the fixing part 60 formed on the inner circumferential surface of the cover part 30 and the cyclone part 20. The upper surface of the impact portion 50 is inserted into and fixed to the upper fixing portion 62 formed on the cover portion 30, the lower surface of the impact portion 50 is on the inner peripheral surface of the cyclone portion 20 It is inserted into and fixed to the lower fixing part 64 formed to protrude.

Fixing projections 66 are formed on the inner circumferential surfaces of the upper fixing portion 62 and the lower fixing portion 64 to be combined with the insertion portions 58 formed in the upper and lower surfaces of the impacting portion 50 so that the collision is formed. The part 50 is more firmly fixed.

When the collision part 50 is completely worn, the collision part 50 may be replaced by opening and closing the cover part 30.

Aggregate from which waste concrete or contaminants are separated by the cyclone part 20 and the collision part 50 is discharged to the aggregate discharge part 70 below the cyclone part 20.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

10: input part 20: cyclone part
22: cylindrical portion 24: cone portion
30: cover part 40: discharge part
50: collision portion 50 ': cylindrical portion collision portion
50 “; Cone impact 52: protrusion
54: space portion 58: insertion portion
60: fixing part 62: upper fixing part

64: lower fixing part 66: fixing protrusion
68: Conical Government 70: Aggregate Discharge Department

Claims (5)

Is provided on one side of the upper portion, and the inlet 10 for introducing the waste into;
A cyclone unit 20 in which the input unit 10 is formed at an upper portion and centrifugally separates the introduced wastes;
A cover part 30 provided on an upper portion of the cyclone part 20 and having a sealing function;
A discharge part 40 provided at the center of the cover part 30 and discharging foreign matter separated from water;
A collision part 50 provided at one side of the cyclone part 20 and separating the introduced waste by collision;
And an aggregate discharge unit (70) connected to the cyclone unit (20) and discharging aggregate from which waste is separated. According to claim 1, wherein the impact portion (50) is made of a wear-resistant material, waste separation device, characterized in that the concave-convex shape is formed on the outer circumferential surface. The waste separation method of claim 1, wherein a space 54 is formed in the collision part 50, and the surface is continuously formed even if the wear occurs in the collision part 52. Device. The method of claim 1, wherein the collision unit 50,
An upper fixing part 62 formed below the cover part 30,
A cylindrical collision part 50 'fixed by a lower fixing part 64 formed on an inner circumferential surface of the cyclone part 20;
Waste concentrator, characterized in that the conical fixing portion 68 and the conical impact portion 50 "fixed between the aggregate discharge portion 70 is separated and assembled respectively. The method of claim 4, wherein
The cylindrical collision part 50 ',
The conical impact portion (50 ") is a waste separation device, characterized in that can be partially replaced according to the wear of each part.

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