KR102269674B1 - Solid-liquid separation system capable of preventing clogging and separating fine particles - Google Patents

Abstract

The present invention relates to a solid-liquid separation system capable of preventing clogging and separating fine particles, so as to easily separate fine particles of a preset particle size or less by an elastic spiral brush screw in the solid-liquid separation process for raw water containing sludge, and improve a through-hole structure of a screen, so that the clogging of the through-hole during the separation and discharge process of the fine particles is prevented. More specifically, a solid-liquid separation drum having an inner space formed in the vertical direction and having an opened upper end, in which a raw water inlet and a separation liquid outlet communicating with the inner space are respectively formed in the lower portion thereof; a solid-liquid separation screen formed on an outer periphery thereof with a plurality of through-holes in a cylindrical shape, installed along the longitudinal direction while forming a distance from an inner periphery of the solid-liquid separation drum, and having a lower portion in communication with the raw water inlet through which sludge containing raw water is introduced; a moving screw that is rotationally driven while passing through a center of the solid-liquid separation screen in the vertical direction, and transfers the sludge flowing into the solid-liquid separation screen toward the upper end of the solid-liquid separation drum, so as to separate and discharge the fine particles during the transferring process; and a solid-liquid separator including a discharge impeller rotationally interlocked with the moving screw, and installed on the opened upper end of the solid-liquid separation drum to discharge upwardly transferred sludge.

Description

Solid-liquid separation system capable of preventing clogging and separating fine particles

The present invention improves the pore structure of the screen while allowing fine particles with a predetermined particle diameter or less to be easily separated by a helical brush screw having elasticity in the solid-liquid separation process for raw water including sludge. It relates to a solid-liquid separation system capable of preventing clogging and separating fine particles.

In general, since various industrial wastewater, sewage, and pig manure contain solids such as sludge, the purification process cannot be performed properly without separating and removing these solids. is removing

In this way, as a conventional device that performs a solid-liquid separation function prior to the purification process, an inlet is formed at the upper portion and the filter tube body is fixed inside a cylindrical body having an outlet at the lower portion through which the desorption filtrate in a state in which solids are removed, and this A device having a structure in which a pressurizing screw operated by a motor is installed so as to be close to the inner circumferential surface of the filter tube body, and a sludge discharge port that is opened only at a predetermined pressure or more is used on the screw tip side of the filter tube body.

However, in this conventional device, as the blades scrape the solids attached to the inner circumferential surface of the filter tube by the rotation of the screw, and pressurize and discharge it while pressing it forward, a lot of pressure is applied to the filter tube body, causing deformation and damage to the filter tube body shape. There is a problem in that the solid material is finely pulverized by the pressing force and passes through the filter body to reduce the dehydration rate.

In addition, since solids are concentrated only on the filter body close to the inlet, the solids separation function of the filter body is reduced. In particular, when a large amount of fine particulate solids are contained, a large amount of fine particulate solids are discharged through the hole of the filter body at once. Because clogging occurs frequently, the efficiency of solid-liquid separation is rapidly reduced, and repeated maintenance is required for the clogged through hole.

Republic of Korea Patent Registration No. 10-1896603 (2018.09.07. Announcement)

Therefore, an object of the present invention is to improve the pore structure of the screen while allowing fine particles with a predetermined particle diameter or less to be easily separated by a helical brush screw having elasticity in the solid-liquid separation process for raw water including sludge to separate and discharge fine particles An object of the present invention is to provide a solid-liquid separation system capable of preventing clogging and separating fine particles that can prevent clogging of through holes during the process.

As a means for solving the above problems, the solid-liquid separation system (hereinafter referred to as the 'solid-liquid separation system of the present invention') capable of preventing clogging and separating fine particles of the present invention has an internal space formed in a vertical direction and an opening at the top. and a solid-liquid separation drum in which a raw water inlet and a separation liquid outlet communicating with the inner space are respectively formed in the lower part, and a plurality of through holes are formed on the outer periphery of the cylindrical shape, and spaced apart from the inner periphery of the solid-liquid separation drum in the longitudinal direction The solid-liquid separation screen is installed along the line and the lower part communicates with the raw water inlet, and the sludge containing raw water flows in, and the solid-liquid separation screen is rotated while penetrating the center of the solid-liquid separation screen in the vertical direction, and the sludge flowing into the solid-liquid separation screen is removed from the solid-liquid separation screen. It is composed of a moving screw that transports the separation drum in the upper direction and separates and discharges fine particles during the transfer process, and a discharge impeller that is installed on the open top of the solid-liquid separation drum in rotation interlocking with the moving screw and discharges the upwardly transferred sludge. It is characterized in that it includes a solid-liquid separator.

As an example, the moving screw is characterized in that it includes a rotating shaft that is rotationally interlocked with a rotational force applied from the outside, and a plurality of brushes helically mounted along the outer periphery of the rotating shaft with an elastic material.

As an example, the moving screw is characterized in that the distance between the tip of the brush and the inner periphery of the solid-liquid separation screen is smaller than the diameter of the through hole.

As an example, a dehydrator configured at the rear end of the solid-liquid separator, into which sludge separated and discharged from the solid-liquid separator is introduced, and the introduced sludge is dehydrated through a screw press method and discharged.

As an example, the dehydrator includes a dewatering drum having an inner space formed in a horizontal direction, one end of which is opened, and a sludge inlet and a dewatering liquid outlet communicating with the inner space are respectively formed in the upper and lower portions, and a cylindrical outer periphery. A screen having a plurality of through holes formed in the and installed along the longitudinal direction while forming a distance from the inner periphery of the dewatering drum, and the upper part of the other end is in communication with the sludge inlet to introduce sludge into the screen, and the center of the screen in the horizontal direction A dewatering screw that is driven to rotate while passing through and is equipped with a spiral screw blade along the longitudinal direction to transfer the sludge delivered to the inside of the screen in the direction of one end of the dewatering drum, and one end of the dewatering drum is mounted to slide through a pressure spring. It is characterized in that it includes a pressing member for applying a pressing force to the transferred sludge while opening and closing the opened one end.

As an example, the through holes of the screen and the solid-liquid separation screen are characterized in that the diameter increases from the inside to the outside.

As an example, the dewatering screw configures the screw blade to be spaced apart from the inner periphery of the screen, has an elastic material, and is attached to surround the outer end of the screw blade, and is spaced apart from the inner periphery of the screen It is characterized in that it includes an adhesive gasket that is in close contact with the .

As described above, the solid-liquid separation system of the present invention provides a solid-liquid separator for performing solid-liquid separation prior to the front end of the dehydrator, and in the case of the solid-liquid separator, fine particles are removed during the movement of sludge through a helical brush screw having elasticity. The solid-liquid separation screen allows easy separation of fine particles by brushing it off the side of the solid-liquid separation screen and improves the structure of the screen opening from the inside to the outside to prevent clogging due to stagnation of the fine particles in the through hole, thereby separating solid-liquid separation. In addition to the improvement of efficiency, there is an effect of reducing the maintenance cost due to the clogging of the through hole.

In addition, in the dehydrator to which the screw press method is applied, a gap is formed between the screw blade and the inner periphery of the screen to prevent physical deformation of the screw, and an adhesive gasket is installed on the outer end of the screw blade, thereby reducing the pressure applied to the sludge. It has the effect of reducing the maintenance cost as a result of improving the durability and lifespan of the screw.

1 is a side cross-sectional view showing a solid-liquid separation system according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line AA′ of FIG. 1 .
3 is a partially enlarged view showing a solid-liquid separation screen and a brush of a moving screw according to an embodiment of the present invention.
4 is a partially enlarged view showing an adhesion gasket of a dewatering screw according to an embodiment of the present invention.

Hereinafter, the configuration and operation of the present invention will be described in more detail based on the accompanying drawings. In describing the present invention, the terms or words used in the present specification and claims are based on the principle that the inventor can appropriately define the concept of the term in order to best describe his invention. It must be interpreted as a meaning and concept consistent with the technical idea of

1 is a side cross-sectional view showing a solid-liquid separation system according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along line A-A' shown in FIG. 1 . 3 is a partially enlarged view showing the solid-liquid separation screen and the brush of the moving screw according to an embodiment of the present invention, and FIG. 4 is a partially enlarged view showing the adhesion gasket of the dewatering screw according to an embodiment of the present invention.

The solid-liquid separation system of the present invention includes a dehydrator 10 that dehydrates sludge by applying a screw press method and is provided at the front end of the dehydrator 10 to perform a solid-liquid separation process prior to the incoming raw water. and a solid-liquid separator 20 for transferring the sludge separated and discharged in the process to the dehydrator 10 .

First, the solid-liquid separator 20 separates and discharges the sludge and the separated liquid with respect to the incoming raw water, and in this process, fine particles containing contaminants or solids having a particle size smaller than a preset particle size can be discharged together with the separated liquid. let it be

That is, the solid-liquid separator 20 separates the separation liquid from the fine particles having a relatively small particle diameter among the incoming raw water prior to the screw press type dehydration treatment of the dehydrator 10, and only the sludge discharged through this treatment process is used in the dehydrator 10 ), so that the treatment load of the wastewater treatment facility connected to the downstream can be reduced.

Specifically, as shown in FIG. 1 , the solid-liquid separator 20 includes a solid-liquid separation drum 200 , a solid-liquid separation screen 210 , a moving screw 220 , and a discharge impeller 230 .

The solid-liquid separation drum 200 has an inner space 203 formed in a vertical direction, and an opening 204 is formed at an upper end thereof. And the solid-liquid separation drum 200 has a raw water inlet 201 and a separated liquid outlet 202 communicating with the internal space 203 on one side and the other side of the lower end, respectively, so that the inflow of raw water and the separated liquid are discharged. make it possible

The solid-liquid separation screen 210 has a cylindrical structure and is fixedly installed along the longitudinal direction while forming a distance from the inner periphery of the solid-liquid separation drum 200 in the inner space 203 of the solid-liquid separation drum 200, A plurality of through holes 211 are formed on the outer periphery.

In addition, the lower portion of the solid-liquid separation screen 210 communicates with the raw water inlet 201 of the solid-liquid separation drum 200 so that raw water can be introduced therein.

For example, in the solid-liquid separation screen 210, a communication port 212 is formed at a position facing the raw water inlet 201 of the solid-liquid separation drum 200, and is injected into the internal space 203 of the solid-liquid separation drum 200. It allows raw water including sludge to be introduced into the solid-liquid separation screen 210 .

The solid-liquid separation screen 210 separates the separated liquid through the through hole 211 in the process in which raw water including the sludge introduced from the communication port 212 is transferred in one direction, that is, in the upper direction by the moving screw 220 to be described below. The separated liquid is discharged, and the separated liquid is dropped and collected in the lower part of the solid-liquid separation drum 200 and discharged to the separation liquid outlet 202 .

Meanwhile, as shown in FIG. 2 , the through hole 211 of the solid-liquid separation screen 210 is preferably configured such that its diameter increases from the inside to the outside in the discharge direction of the separation liquid.

That is, the expanded structure of the through hole 211 in the solid-liquid separation screen 210 prevents clogging due to stagnation of the fine particles discharged from the through hole 211 during the solid-liquid separation process, as well as facilitates the flow and discharge of the fine particles. As a result, it is possible to prevent blockage of the through hole 211 by doing so.

The through hole 211 not only allows the separation liquid to be discharged with respect to the raw water including the sludge as described above, but also allows fine particles having a particle diameter less than a set particle diameter to be separated and discharged through the selection of the diameter of the through hole 211 .

Here, the through hole 211 of the solid-liquid separation screen 210 for separating and discharging fine particles is preferably configured to have a diameter of 0.02 to 0.04 mm.

The moving screw 220 is rotationally driven by a rotational force applied from the outside while passing through the centers of the solid-liquid separation screen 210 and the solid-liquid separation drum 200 .

For example, the moving screw 220 includes a rotating shaft 221 having one end connected to the driving motor 21 while passing through the centers of the solid-liquid separation screen 210 and the solid-liquid separation drum 200 , and the driving motor 11 . ) and is capable of rotationally interlocking with the operation, and includes a plurality of brushes 222 mounted to take a spiral shape along the outer periphery of the rotation shaft 221 with an elastic material.

Since the brush 222 has a spiral structure in its overall shape, the sludge introduced into the solid-liquid separation screen 210 can be moved in the direction in which the upper end of the solid-liquid separation drum 200, that is, the opening portion 204 is formed. , the fine particles contained in the raw water are brushed off toward the inner periphery of the solid-liquid separation screen 210 through centrifugal force and elastic force according to the rotational driving of the moving screw 220 to have a relatively smaller particle diameter than the diameter of the through hole 211 It allows the fine particles to be separated and discharged through the through hole 211 .

Here, the brush 222 is configured to have a length that can be in close contact with the inner periphery of the solid-liquid separation screen 210 as much as possible. The solid-liquid separation is made up to the particles, and in particular, as shown in FIG. 2 , the separation distance B between the tip of the brush 222 and the inner periphery of the solid-liquid separation screen 210 is the diameter (A) of the through hole 211 . It is formed smaller so that the through hole 211 is not blocked while inducing the movement of the fine particles.

In addition, it is preferable that at least one brush 222 selected from among the plurality of brushes 222 has a relatively longer length than the length from the outer periphery of the rotation shaft 221 to the inner periphery of the solid-liquid separation screen 210 .

This is to allow the end of some brushes 222 to be drawn into the through hole 211 during the rotation of the moving screw 220, and by directly hitting the inner periphery of the through hole 211 with the elastic force of the brush 222, This is to prevent occlusion of the through-hole 211 by allowing foreign substances deposited in the through-hole 211 to be detached by impact.

In addition, unlike the metal screw blade, the brush 222 can rotate while maintaining the maximum close contact with the inner periphery of the solid-liquid separation screen 210 , so that foreign substances adhered to the inner periphery of the solid-liquid separation screen 210 . together with the through hole 211, it is possible to prevent a decrease in load due to foreign substances.

The discharge impeller 230 discharges the sludge upwardly transferred by the moving screw 220 to the outside.

The discharge impeller 230 is rotationally interlocked with the moving screw 220 and is installed at the open upper end of the solid-liquid separation drum 200 to separate the solid-liquid sludge transferred from the inside of the solid-liquid separation screen 210 in the upper direction. Discharge into the opening (204) of the drum (200).

As shown in FIG. 1 , the sludge discharged by the discharge impeller 230 can be transferred and delivered through the communication pipe 240 connected to the dewatering drum 200 of the dehydrator 10 .

On the other hand, the dehydrator 10 is configured at the rear end of the solid-liquid separator 20, and the sludge separated and discharged from the solid-liquid separator 20 is introduced, and the introduced sludge is dehydrated through a screw press method and discharged. 1 , it is configured to include a dewatering drum 100 , a screen 110 , a dewatering screw 120 , and a pressing member 130 .

The dewatering drum 100 has an inner space 103 formed in a horizontal direction, and an opening 104 is formed at one end. In addition, the dewatering drum 100 has a sludge inlet 101 communicating with the internal space 103 at the upper portion of the other end, and a dewatering liquid outlet 102 at the lower end thereof.

The screen 110 has a cylindrical structure and is fixedly installed along the longitudinal direction while forming a spaced distance from the inner periphery of the dewatering drum 100 in the inner space 103 of the dewatering drum 100, and the outer periphery has an inner and A plurality of through-holes 111 to communicate are formed.

In addition, the screen 110 has a communication port 112 formed at a position facing the sludge inlet 101 of the dewatering drum 100 so that the sludge transferred to the internal space 103 of the dewatering drum 100 is transferred to the screen ( 110) so that it can be introduced into the interior of the

The screen 110 allows the dewatering liquid dewatered from the sludge to be discharged through the through hole 111 while the sludge introduced from the sludge inlet 101 is moved in one direction by the dewatering screw 120 to be described below. The separated and discharged dewatering liquid is collected at the lower portion of the dewatering drum 100 and discharged to the dewatering liquid outlet 102 .

At this time, the lower part of the dewatering drum 100 where the dewatering liquid outlet 102 is formed has a cross-section with a downward slope toward the dewatering liquid outlet 102, so that the dewatering liquid discharged from the screen 110 is dehydrated. To be easily guided in the direction of the liquid outlet (102).

And, as shown in FIG. 4 , the through hole 111 of the screen 110 is preferably configured such that its diameter increases from the inside to the outside. This is also the same as the through hole 211 of the solid-liquid separation screen 210 . A functional effect is derived to prevent a decrease in dehydration efficiency due to blockage of the through hole 111 .

The dewatering screw 120 is rotated by a rotational force applied from the outside while passing through the center of the screen 110 and the dewatering drum 100, and a spiral screw blade 121 is mounted along the longitudinal direction.

For example, as shown in FIG. 1 , the dewatering screw 120 is installed on a rotating shaft having one end connected to the driving motor 11 while passing through the center of the screen 110 and the dewatering drum 100 , and the driving motor ( 11), the rotational force can be shared and rotationally interlocked.

When the dewatering screw 120 is rotated by the spiral screw blade 121, the sludge introduced into the screen 110 is transferred to one end of the dewatering drum 100, that is, to the position where the opening 104 is formed. .

Here, in the dewatering screw 120, the end of the screw blade 121 should be in close contact with the inner periphery of the screen 110 as much as possible so as not to decrease the dewatering efficiency in performing dewatering treatment using the screw press method. In this case, the dewatering screw According to the repeated rotational driving of 120, the screw blade 121 is deformed such as wear or breakage due to friction, so that irregular spacing occurs between the inner periphery of the screen 110 during long-term use, so that the dewatering efficiency is gradually reduced. In addition, there is a problem in that the maintenance period due to the deformation of the screw blade 121 is shortened and consequently the operating cost of the device is increased.

Accordingly, the dewatering screw 120 according to an embodiment of the present invention constitutes the screw blade 121 so as to form a certain distance from the inner periphery of the screen 110 as shown in FIG. 4, and includes urethane, etc. and an adhesive gasket 122 having an elastic material and being attached to surround the outer end of the screw blade 121 so as to be in close contact with the inner periphery of the screen 110 spaced apart.

That is, the adhesion gasket 122 keeps the screw blade 122 in close contact with the inner periphery of the screen 110 and protects the outer end of the screw blade 121 from friction, etc. It is possible to prevent a decrease in efficiency and improve the durability of the screw blade 122, thereby reducing maintenance costs.

At this time, although the adhesion gasket 122 is not shown in the drawings, it is preferable to have a structure detachable from the outer end of the screw blade 121 .

The pressing member 130 is mounted on one end of the dewatering drum 100 to slide through a pressing spring 134 to open and close the opening 104 of one end of the dewatering drum 100, and to the dewatering screw 120. A pressing force is applied to the sludge transported by the

Referring to FIG. 1 , the pressing member 130 is fixedly installed on the opened end of the dewatering drum 100 and communicates with the opening 104 so that the sludge transferred by the dewatering screw 120 can pass therethrough. and a fixing plate 131 having a hollow formed therein, and one or more sliding bars 133 coupled to the fixing plate 131 in the transverse direction and partially exposed to the outside of one end of the dewatering drum 100 .

And the pressing member 130 is located on the outside of one end of the dewatering drum 100, the sliding bar 133 is penetrated through the movable plate 132 and the sliding bar that slides in the lateral direction from the fixed plate 131 ( 133) includes a pressing spring 134 mounted on the flow plate 132 to apply a pressing force toward one end of the dewatering drum 100.

The flow plate 132 is kept in close contact with one end of the dewatering drum 100 by a constant pressing force of the pressure spring 134 to close the opening 104, and the dewatering screw 120 When the sludge introduced by operation is moved to the flow plate 132 and continuously stacked, the pressing force of the pressure spring 134 resists the moving force of the sludge and compresses the moving sludge, and in this process, the sludge is The contained moisture is discharged as a dewatering solution through the through hole 111 of the screen 110, so that the dewatering treatment of the sludge is performed.

Afterwards, when the moving force of the sludge is gradually increased, a force relatively greater than the pressing force of the pressing spring 134 is applied. As the flow plate 132 slides from the fixed plate 131 , the opening 104 is ) is opened, and the dewatered sludge is sequentially discharged to the outside through the opening 104 above.

Those skilled in the art from the above description will be able to see that various changes and modifications are possible without departing from the technical spirit of the present invention. Accordingly, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

10: dehydrator 20: solid-liquid separator
100: dehydration drum 110: screen
111: through hole 120: dewatering screw
121: screw blade 122: adhesive gasket
130: pressing member 132: flow plate
133: sliding bar 134: pressure spring
200: solid-liquid separation drum 210: solid-liquid separation screen
211: through hole 220: moving screw
222: brush 230: exhaust impeller

Claims (7)

A solid-liquid separation drum having an inner space formed in a vertical direction, an upper end is opened, and a raw water inlet and a separated liquid outlet communicating with the inner space are respectively formed at the lower portion, and a plurality of through holes are formed on the outer periphery of the cylindrical shape, and the solid-liquid separation The solid-liquid separation screen is installed along the longitudinal direction while forming a spaced distance from the inner periphery of the drum, and the lower part communicates with the raw water inlet through which sludge containing raw water flows, and the solid-liquid separation screen passes through the center of the solid-liquid separation screen in the vertical direction and rotates and a moving screw that transports the sludge flowing into the solid-liquid separation screen toward the upper end of the solid-liquid separation drum and separates and discharges fine particles during the transfer process, and is rotationally interlocked with the moving screw and installed at the open top of the solid-liquid separation drum a solid-liquid separator comprising a discharge impeller for discharging the upwardly transported sludge; and
A dewatering drum having an inner space formed in the horizontal direction, one end of which is opened, and a sludge inlet and a dewatering liquid outlet communicating with the inner space are respectively formed in the upper and lower portions, and a plurality of through holes are formed on the outer periphery in a cylindrical shape, and the dewatering It is installed along the longitudinal direction while forming a distance from the inner periphery of the drum, and the upper part of the other end communicates with the sludge inlet to allow sludge to flow into the screen, and it is rotated and driven while passing through the center of the screen in the horizontal direction in the longitudinal direction. A dewatering screw equipped with a spiral screw blade to transfer the sludge delivered to the inside of the screen in the direction of one end of the dewatering drum, and a sludge mounted to one end of the dewatering drum to slide through a pressure spring to open and close the opened end. A dehydrator comprising a pressing member for applying a pressing force to the solid-liquid separator, configured at the rear end of the solid-liquid separator, into which the sludge separated and discharged from the solid-liquid separator is introduced, and the introduced sludge is dehydrated through a screw press method and discharged. ,
The moving screw includes a rotating shaft that is rotationally interlocked with a rotational force applied from the outside and a plurality of brushes helically mounted along the outer periphery of the rotating shaft with an elastic material between the tip of the brush and the inner periphery of the solid-liquid separation screen. The separation distance is formed smaller than the through hole diameter of the solid-liquid separation screen,
The through holes of the screen and the solid-liquid separation screen are configured to increase in diameter from the inside to the outside,
The dewatering screw constitutes the screw blade so as to be spaced apart from the inner periphery of the screen, has an elastic material, and is attached to surround the outer end of the screw blade and is in close contact with the inner periphery of the screen spaced apart. A solid-liquid separation system capable of preventing clogging and separating fine particles, comprising: delete delete delete delete delete delete

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