KR20120088044A - Hydrocyclone for controling length of vortex finder, apparatus and method for separating aggregate of dredge deposit soil using thereof - Google Patents

Abstract

PURPOSE: A hydro cyclone for controlling length of vortex finder, apparatus and method for separating aggregate of dredge deposit soil using thereof are provided to separate dredging sediment by particle size and to enhance recycle rate. CONSTITUTION: A hydro cyclone for controlling length of vortex finder comprises a case(10), an inlet pipe(20), and an overflow orifice(30) and a vortex finder. The case is formed into a conical shape. The case is elevated and descended by screwed with the vortex finder. In the case, a cylinder shaped connecting member of a first screw tap is installed inside the upper center part. The inlet pipe is projected and formed in a horizontal direction from the upper end part of the case. The overflow orifice is formed at the bottom surface of the case. The vortex finder is perpendicularly formed at the upper center part of the case.

Description

HYDROCYCLONE FOR CONTROLING LENGTH OF VORTEX FINDER, APPARATUS AND METHOD FOR SEPARATING AGGREGATE OF DREDGE DEPOSIT SOIL USING THEREOF}

The present invention relates to a hydrocyclone capable of adjusting the length of a vortex finder, and to an apparatus and method for separating dredged sediment aggregate using the same, in detail, collecting fine soil installed on top of a hydrocyclone, which is one of the factors that can determine the selection particle size. The present invention relates to a hydrocyclone capable of adjusting the length of a vortex finder, and a dredged sediment aggregate separating device and method using the same.

In the rivers, lakes, conduits and ports, deposits of various particles occur, which not only contain various pollutants, but also limit dredging capacity, and dredge to prevent them. It leads to business.

Dredged sediment has various particle distributions and pollution distributions, and there is a problem of treatment and disposal when a large amount of dredged soil is generated. Various techniques have been developed to select and recycle the appropriate aggregate in dredged soil.

In general, the method of separating dredged soil is separated by particle size by applying a physical method such as a sieve, particle diameter 2.0mm or more is easy to select, but the particle size of less than that occurs due to the effects of dredged soil moisture. For this purpose, fine dredged soils are selected, including the hydrocyclone process.

Cyclones are widely used in various technical sites. For example, cyclones are used for gas purification, combustion, spraying, powder fractionation, etc., and for solid-liquid separation. Cyclone is specially designed for the treatment of liquid phases and is called hydrocyclone or hydrocyclone.

The basic separation principle of the cyclone is centrifugal precipitation. That is, suspended particles are subject to centrifugal acceleration, which causes them to separate from the fluid. Unlike the centrifuge, there are no moving parts in the cyclone, and the required vortex motion is achieved by the force of the fluid itself.

The hydrocyclone has a cylindrically coupled cylinder. Suspended particles in the fluid flow tangentially through the inlet located at the top of the cylinder. Due to the tangential inflow, a strong vortex movement occurs inside the cyclone. Part of the fluid containing the microparticles is discharged through the cylinder tube fixed in the upper center, and a small distance into the cylinder. This discharge pipe is called an overflow pipe or vortex finder here. Residual liquid or coarse particles are removed through a circular opening located below the cone, which is called an underflow orifice.

The hydrocyclone applied to screen the fine dredged soil has a problem that the vortex finder described above is fixed so that dredged soil other than the conditions designed based on the properties of the dredged soil does not achieve the desired screening effect upon inflow.

In particular, when the properties of dredged soils are not homogeneous, it is difficult to achieve homogeneous particle size separation targets when applying hydrocyclones designed based on the properties of dredged soils determined by the representative value. In other words, even the dredged soils in the same site will have various particle size distributions, and in the case of fine soils containing most pollutants, their margins will be different. For example, if the maximum particle diameter of zone A is 1 mm, while the maximum particle diameter of zone B is 0.5 mm, hydrocyclone is designed for dredged soil conditions in zone B. Contaminated soils in between are incorporated into non-contaminated aggregates that can not be separated and recycled, requiring further cleaning. This immediately leads to an increase in dredged soil treatment costs and time.

The present invention is to solve the above problems, in various conditions by configuring to change the insertion length in the container of the vortex finder collecting the fine soil installed on the top of the hydrocyclone, which is one of the factors that can determine the selection particle diameter Hydrocyclone with adjustable vortex finder length to maintain homogeneous resolution by changing the length of the dredged soil at the site according to the properties of the dredged soil, and to select and recycle only the required particle size even by changing the insertion length; An object of the present invention is to provide an apparatus and method for separating dredged sediment aggregate using the same.

In addition, the present invention is to be recycled because it is not contaminated with the sediment to be disposed of due to pollution by separating the dredged sediment which is currently designated as designated waste or recycled through proper physical / chemical treatment of the entire dredged soil at the time of recycling. It is another object of the present invention to provide a hydrocyclone that can adjust the length of the vortex finder, which can be separated into the site and improve the recycling rate and reduce the treatment cost, and a dredged sediment aggregate separation device and method using the same.

Features of the present invention for achieving the above object,

A case formed in a conical shape; An inlet pipe protruding from the upper side of the case in a horizontal direction; An overflow orifice formed on the bottom of the case; Is formed vertically in the center of the upper surface of the case, characterized in that consisting of a vortex finder is installed to move up and down.

Here, the case is provided with a cylindrical fastening member formed of a first screw tab on the inner side in the upper center portion so that the vortex finder is screwed up and down and supported.

Here, the fastening member is a slewing bearing in which a gear is formed on the outer ring and the first screw tab is formed on the inner ring.

Here, the slewing bearing further includes a stepper motor engaged with the gear of the outer ring under external control to rotate the inner ring to adjust the length of the vortex finder of the hydrocyclone engaged with the first screw tab. do.

Here, the vortex finder is formed so that the second screw tab is formed on the upper end of the outer surface to be engaged with the fastening member.

Here, the vortex finder is adjusted in length up to 40% of the distance from the start of the inclined plane of the case to the end of the overflow orifice.

According to another aspect of the present invention,

A storage tank in which dredged sedimentary soil having a particle diameter of 2 mm or less after being dredged to the ground is introduced and mixed with water at a ratio of 1: 1; A pump for pumping the mixed liquid stored in the reservoir; The dredged sedimentary soil is separated by particle diameter by adjusting the length of the vortex finder by receiving the mixed liquid fed from the pumping pump into the inlet pipe and discharging the mixed liquid containing the dredged sedimentary soil having a relatively small particle size through the vortex finder. Hydrocyclones for discharging the mixed liquid containing the dredged sedimentary soil of the particle size through an overflow orifice; A first baffle for storing the mixed liquid discharged from the vortex finder of the hydrocyclone; And a second baffle in which the mixed liquid discharged from the overflow orifice of the hydrocyclone is stored.

Here, the hydrocyclone is provided with a cylindrical fastening member formed of a first screw tab on the inner side in the upper center portion so that the vortex finder is screwed vertically in the upper surface center portion to move up and down.

Here, the vortex finder is formed with a second screw tab on the upper end of the outer surface to be engaged with the fastening member.

Here, the vortex finder is adjusted in length up to 40% of the distance from the start of the inclined plane of the case to the end of the overflow orifice.

Here, the fastening member of the hydrocyclone is a slewing bearing in which a gear is formed on the outer ring and the first screw tab is formed on the inner ring.

Here, the slewing bearing is further provided with a step motor which is engaged with the gear of the outer ring to rotate the inner ring to adjust the length of the vortex finder of the hydrocyclone engaged with the first screw tab.

Here, the step motor is installed in the reservoir, the particle sensor for checking the average particle diameter of the dredged sediment of the mixed liquid stored in the reservoir; A turbidity sensor installed in the reservoir and checking contamination of the mixed liquid stored in the reservoir; And a controller for controlling the amount of rotation of the step motor according to the sensing values input from the particle sensor and the turbidity sensor to adjust the length of the vortex finder of the hydrocyclone according to the particle size and the degree of contamination.

Here, a pressure gauge for checking the pressure inside the pipeline is further provided on the pipeline between the pressure pump and the hydrocyclone.

Here, the pressure pump is provided with an inverter for adjusting the flow rate of the pressure pump.

According to still another aspect of the present invention,

In the method of separating dredged sediment aggregate using a hydrocyclone capable of adjusting the length of the vortex finder using the dredged sediment aggregate separating apparatus, the dredged sediment having a particle diameter of 2 mm or less sifted after ground is 1: 1 A storage step of mixing at a ratio of and storing the mixture in a storage tank; A pressure feeding step of feeding the mixed liquid stored in the reservoir into the hydrocyclone through a pressure pump; The mixed solution is introduced into the hydrocyclone inlet pipe, and the dredged sediment is separated by particle size by adjusting the length of the vortex finder, and the mixed liquid containing the dredged sedimented soil having a relatively small particle diameter is discharged through the vortex finder, and the relatively large particle size is obtained. A separation process of discharging the mixed solution containing the dredged sediment of the through the overflow orifice; And storing the mixed liquid discharged from the vortex finder of the hydrocyclone in the first baffle and storing the mixed liquid discharged from the overflow orifice of the hydrocyclone in the second baffle.

Here, the separation process checks the average particle diameter of the dredged sedimentary soil and the contaminating property of the mixed liquid of the reservoir to automatically or manually adjust the length of the vortex finder of the hydrocyclone according to the particle size and the degree of contamination.

According to the present invention, the vortex finder can control the hydrocyclone and the dredged sediment aggregate aggregate separation apparatus and method using the same, collecting fine soil installed on the hydrocyclone, which is one of the factors that can determine the selection particle size By adjusting the insertion length in the container of the vortex finder, the length of the dredged soil can be changed in the field according to the properties of dredged soils under various conditions to maintain homogeneous resolution and to select only the required particle size even by changing the insertion length. Can be recycled.

In addition, according to the present invention, the dredged sediments that are currently designated as designated wastes or disposed of or recycled through proper physical / chemical treatment of the entire dredged soil are separated by particle diameter so that they are not contaminated with sediments to be disposed of due to pollution. Separating on site as recyclable sediments can not only increase the recycling rate but also reduce the disposal cost.

1 is a perspective view showing the configuration of a hydrocyclone capable of adjusting the vortex finder length according to the present invention.
2 is a side cross-sectional view of FIG. 1.
Figure 3 is a perspective view showing the configuration of a hydrocyclone adjustable vortex finder length in accordance with another embodiment of the present invention.
4 is a side cross-sectional view of FIG. 3.
Figure 5 is a schematic diagram showing the configuration of the dredged sediment aggregate separation device using a hydrocyclone adjustable vortex finder length in accordance with the present invention.
6 is a flowchart illustrating a method for separating dredged sediment aggregate using a hydrocyclone capable of adjusting the length of a vortex finder according to the present invention.
7 to 10 is a view showing the modeling results of a hydrocyclone capable of adjusting the vortex finder length in accordance with the present invention.

Hereinafter, with reference to the accompanying drawings the configuration of a hydrocyclone capable of adjusting the vortex finder length according to the present invention will be described in detail.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

1 is a perspective view showing the configuration of a hydrocyclone adjustable vortex finder length according to the present invention, Figure 2 is a side cross-sectional view of Figure 1, Figure 3 is a vortex finder length adjustable hydro according to an embodiment of the present invention It is a perspective view which shows the structure of a cyclone, and FIG. 4 is a side cross-sectional view of FIG.

1 to 4, the vortex finder length adjustable hydrocyclone 1 according to the present invention includes a case 10, an inlet pipe 20, an overflow orifice 30, and a vortex finder 40. It consists of

First, the case 10 is formed in a conical shape in a normal shape, and a cylindrical fastening member 13 formed of the first screw tab 11 is provided inside the central portion of the upper surface. Here, the fastening member 13 may be formed of a nut as shown in FIGS. 1 and 2, the gear 13b is formed in the outer ring 13a as shown in FIGS. 3 and 4, and the inner ring The slewing bearing in which the 1st screw tab 11 was formed in 13c may be applied. In this case, when the slewing bearing is applied, it is engaged with the gear 13b of the outer ring 13a, rotated under external control, and rotated with the first screw tab 11 by rotating the inner ring 13c. Step motor 50 for adjusting the protruding length of the vortex finder 40 may be further provided. At this time, it is preferable that the gear 13b of the outer ring 13a is connected to the chain 51 by the rotational step of the step motor 50, and the rotation shaft and the gear 13b may be directly connected.

And, the inlet pipe 20 is formed to protrude in the horizontal direction from the upper side of the case in a conventional form.

In addition, the overflow orifice 30 is formed on the bottom surface of the case 10 in a conventional form.

In addition, the vortex finder 40 is formed in a cylindrical shape in which the upper and lower ends are vertically installed at the center of the upper surface of the case 10, and the second screw tab 41 is formed at the upper end of the outer surface to be fastened to the fastening member 13. Is formed. Here, the vortex finder 40 is 40% from the start point S1 to the end point S2 of the distance L1 from the inclined plane start point S1 of the case 10 to the end point S2 of the overflow orifice 30. The length is adjusted to the point. That is, when the distance L1 is 1 m, the length of the vortex finder 40 is 40 cm.

Hereinafter, the configuration of a dredged sediment aggregate aggregate device using a hydrocyclone capable of adjusting the length of the vortex finder according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 5 is a schematic diagram showing the configuration of the dredged sediment aggregate separation device using a hydrocyclone adjustable vortex finder length in accordance with the present invention.

Referring to Figure 5, dredged sediment aggregate aggregate device 100 using a hydrocyclone capable of adjusting the length of the vortex finder according to the present invention, the reservoir 110, the pressure pump 120, the hydrocyclone (1) and And a first baffle 130 and a second baffle 140.

First, the storage tank 110 is dredged sedimentary sedimentary soil having a particle diameter of 2 mm or less after being dredged into the ground is mixed and stored in a ratio of 1: 1 with water. Here, the reservoir 110 is preferably provided with a stirrer 111.

Then, the pressure pump 120 pumps the mixed solution stored in the reservoir 110 to the hydrocyclone (1) to be described below through a pipe line. Here, the pressure pump 120 is provided with an inverter 121 for adjusting the flow rate of the pressure pump 120. Here, the pressure gauge 123 for checking the pressure inside the pipeline is further provided on the pipeline.

In addition, the hydrocyclone (1) has the same configuration as above, and is connected to the pressure pump 120 and the pipe.

In addition, the first baffle 130 stores a mixed liquid containing a dredged sedimentary soil having a relatively small particle size discharged from the vortex finder 40 of the hydrocyclone 1.

On the other hand, the second baffle 140 stores a mixed liquid containing a dredged sedimentary soil having a relatively large particle size discharged from the overflow orifice 30 of the hydrocyclone 1.

And, the step motor installed in the hydrocyclone (1) can be adjusted manually or automatically.

When the step motor 50 is automatically adjusted, the particle sensor 150, the turbidity sensor 160, and the controller 170 are further provided.

The particle sensor 150 is installed in the reservoir 110 and checks the average particle diameter of the dredged sedimentary soil of the mixed liquid stored in the reservoir 110.

The turbidity sensor 160 is installed in the reservoir 110, and checks the contamination state of the mixed liquid stored in the reservoir 110.

The controller 170 controls the amount of rotation of the step motor 50 in accordance with the sensing values input from the particle sensor 150 and the turbidity sensor 160 to determine the vortex finder 40 of the hydrocyclone 1 in accordance with the particle size and contamination. Adjust the length according to the preset value. In this case, the controller 170 compares the sensing values input from the particle sensor 150 and the turbidity sensor 160 with a reference value, compares a difference value with the reference value with a table, and extracts a preset value and adjusts it. In addition, the controller 170 may control the inverter 121 through a value output from the pressure gauge 123 to adjust the flow rate of the pressure pump 120.

Hereinafter, a method for separating dredged sediment aggregate using a hydrocyclone capable of adjusting the length of a vortex finder according to the present invention will be described in detail with reference to the accompanying drawings.

6 is a flowchart illustrating a method for separating dredged sediment aggregate using a hydrocyclone capable of adjusting the length of a vortex finder according to the present invention.

Dredged sedimentary soil having a particle diameter of 2 mm or less after being dredged to the ground is mixed with water in a ratio of 1: 1 and stored in the storage tank 110 (S100).

Then, the mixed liquid stored in the reservoir 110 is pumped to the hydrocyclone 1 through the pressure pump 120 (S120).

Then, the mixed liquid flows into the inlet pipe 10 of the hydrocyclone 1, and the dredged sediment is separated by particle diameter according to the length of the vortex finder 40, and the mixed liquid containing the dredged sedimentary soil having a relatively small particle diameter is vortex finder. Discharged through the 40, the mixed liquid containing the dredged sedimentary soil of a relatively large particle size is discharged through the overflow orifice (30). At this time, the controller 170 controls the rotation amount of the step motor 50 according to the sensing values input from the particle sensor 150 and the turbidity sensor 160 to determine the vortex finder of the hydrocyclone 1 according to the particle size and the contamination degree. The insertion length of 40 is adjusted according to the preset value (S130).

Thus, the mixed liquid discharged from the vortex finder 40 of the hydrocyclone 1 is stored in the first baffle 130, and the mixed liquid discharged from the overflow orifice 30 of the hydrocyclone 1 is second. The baffle 140 is stored (S140).

On the other hand, modeling of a hydrocyclone capable of adjusting the vortex finder length according to the present invention was carried out.

The driving conditions of the hydrocyclone were fixed, and modeling was performed to examine the characteristics of the change in the insertion length of the vortex finder.

The reason for fixing the driving conditions is that it is not easy to change the driving conditions in the actual dredged soil sorting site, so the speed change in the cyclone was modeled by adjusting the insertion length of the vortex finder according to the present invention. As the flow velocity inside the cyclone case increases, it can be judged that fine particle diameter can be selected.

(1) Analysis shape and condition

Analysis conditions, working fluid basic conditions, conditions such as the internal length of the vortex finder are shown in Table 1 below, and the basic model structure is shown in FIG.

Analysis condition Red fluid Vortex Finder Insertion Length -Inflow Speed: 0.8m / s
Outlet: Atmospheric pressure Density: 1000 kg / m3
Viscosity: 0.003 kg / m ?? s 130, 180, 230 mm

(2) Analysis result

Speed contour and vector results

When the internal length of the vortex finder, that is, the insertion length is 230 mm, modeling results of the speed contour and the vector are shown in FIG. 8.

The result of the change in the speed contour according to the change in the internal length of the vortex finder is shown in FIGS. 9 and 10 according to the section position.

② Outflow rate comparison result

If the internal length of the vortex finder is changed from 130mm to 230mm, the flow velocity gradually increases as the insertion length becomes longer. Therefore, when the vortex finder is designed to move in the vertical direction during the production of the hydrocyclone, the separation efficiency can be adjusted in the field. In other words, the larger the insertion length, the less dredged soil can be selected.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

1: hydrocyclone 10: case
20: inlet pipe 30: overflow orifice
40: vortex finder 50: step motor
100: dredge sediment aggregate aggregate separation device
110: reservoir 120: pressure pump
130, 140: first and second baffle 150: particle sensor
160: turbidity sensor 170: controller

Claims (17)

A case formed in a conical shape;
An inlet pipe protruding from the upper side of the case in a horizontal direction;
An overflow orifice formed on the bottom of the case;
Is formed vertically in the center of the upper surface of the case, the vortex finder length adjustable hydrocyclone characterized in that consisting of a vortex finder is installed to move up and down. The method of claim 1,
In this case,
A vortex finder length adjustable hydrocyclone, characterized in that the cylindrical fastening member formed of the first screw tab is installed inside the central portion of the upper surface so that the vortex finder is screwed up and down and supported. The method of claim 2,
The fastening member,
A vortex finder length adjustable hydrocyclone characterized in that the gear is formed on the outer ring, the first bearing tab is formed on the inner ring. The method of claim 3, wherein
In the slewing bearing,
Vortex finder length, characterized in that the step motor is engaged with the gear of the outer ring to adjust the length of the vortex finder of the hydrocyclone fastened to the first screw tab by engaging the gear of the outer ring under external control. Adjustable hydrocyclone. The method of claim 2,
The vortex finder,
A vortex finder length adjustable hydrocyclone, characterized in that the second screw tab is formed on the top of the outer surface to be fastened with the fastening member. The method of claim 5, wherein
The vortex finder,
A vortex finder length adjustable hydrocyclone, characterized in that the length is adjusted to 40% of the distance from the starting point of the inclined surface of the case to the end point of the overflow orifice. A storage tank in which dredged sedimentary soil having a particle diameter of 2 mm or less after being dredged to the ground is introduced and mixed with water at a ratio of 1: 1;
A pump for pumping the mixed liquid stored in the reservoir;
The dredged sedimentary soil is separated by particle diameter by adjusting the length of the vortex finder by receiving the mixed liquid fed from the pumping pump into the inlet pipe and discharging the mixed liquid containing the dredged sedimentary soil having a relatively small particle size through the vortex finder. Hydrocyclones for discharging the mixed liquid containing the dredged sedimentary soil of the particle size through an overflow orifice;
A first baffle for storing the mixed liquid discharged from the vortex finder of the hydrocyclone; And
Dredged sediment aggregate separation device using a hydrocyclone adjustable vortex finder length, characterized in that made of a second baffle that is stored in the mixed liquid discharged from the overflow orifice of the hydrocyclone. The method of claim 7, wherein
The hydrocyclone,
Dredging using a hydrocyclone capable of adjusting the length of the vortex finder, characterized in that the cylindrical fastening member formed of the first screw tab is installed on the inner side of the upper surface so that the vortex finder is screwed vertically at the upper surface of the upper surface. Sediment aggregate separation device. The method of claim 8,
The vortex finder,
Dredge sediment aggregate separation device using a hydrocyclone adjustable vortex finder length, characterized in that the second screw tab is formed on the upper outer surface to be fastened with the fastening member. The method of claim 9,
The vortex finder,
Dredge sediment aggregate separation device using a hydrocyclone adjustable length of the vortex finder, characterized in that the length is adjusted to 40% of the distance from the starting point of the inclined surface of the case to the end point of the overflow orifice. The method of claim 8,
The fastening member of the hydrocyclone,
A dredged sediment aggregate aggregate device using a hydrocyclone capable of adjusting the length of a vortex finder, wherein the gear is formed on the outer ring and the first screw tab is formed on the inner ring. The method of claim 11,
In the slewing bearing,
A hydrocyclone capable of adjusting the vortex finder length may further include a step motor that is engaged with the gear of the outer ring to rotate the inner ring to adjust the length of the vortex finder of the hydrocyclone engaged with the first screw tab. Dredged sediment aggregate separation device using The method of claim 12,
The step motor,
A particle sensor installed in the reservoir and checking an average particle diameter of the dredged sedimentary soil of the mixed liquid stored in the reservoir;
A turbidity sensor installed in the reservoir and checking contamination of the mixed liquid stored in the reservoir; And
Vortex finder length characterized in that the controller for controlling the rotation amount of the step motor in accordance with the sensing value input from the particle sensor and turbidity sensor to adjust the length of the vortex finder of the hydrocyclone according to the particle size and contamination degree Dredged sediment aggregate separation device using an adjustable hydrocyclone. The method of claim 7, wherein
On the pipeline of the pressure pump and hydrocyclone,
Hydrocyclone adjustable vortex finder, characterized in that the pressure gauge is further installed to check the pressure inside the pipe. 15. The method of claim 14,
In the pressure pump,
Dredged sediment aggregate separation device using a hydrocyclone capable of adjusting the vortex finder length, characterized in that the inverter is provided for adjusting the flow rate of the pressure pump. In the method of separating the dredged sediment aggregate using a hydrocyclone capable of adjusting the length of the vortex finder using the dredged sediment aggregate aggregate separation apparatus of claim 7,
A storage step of mixing the dredged sedimentary soil having a particle size of 2 mm or less after being dredged on the ground with water at a ratio of 1: 1 and storing in a storage tank;
A pressure feeding step of feeding the mixed liquid stored in the reservoir into the hydrocyclone through a pressure pump;
The mixed solution is introduced into the hydrocyclone inlet pipe, and the dredged sediment is separated by particle size by adjusting the length of the vortex finder, and the mixed liquid containing the dredged sedimented soil having a relatively small particle diameter is discharged through the vortex finder, and the relatively large particle size is obtained. A separation process of discharging the mixed solution containing the dredged sediment of the through the overflow orifice; And
And storing the mixed liquid discharged from the vortex finder of the hydrocyclone in a first baffle, and storing the mixed liquid discharged from the overflow orifice of the hydrocyclone in a second baffle. Method for separating dredged sediment aggregate using available hydrocyclones. 17. The method of claim 16,
The separation process,
Hydrocyclone with adjustable vortex finder length, characterized in that the length of the vortex finder of the hydrocyclone is automatically or manually adjusted according to the particle size and the degree of contamination by checking the average particle diameter of the dredged sedimentary soil of the mixed solution of the reservoir and the degree of contamination. Separation method of dredged sediment aggregate using the

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