KR102339096B1 - Hydro Cyclone and Wastewater Treatment System Using the Same - Google Patents

Abstract

The present invention has the following configuration.
a cylindrical portion having a cylindrical shape;
In the hydrocyclone composed of a conical part under the cylindrical part,
an inlet formed in the cylindrical part;
an outlet configured to face upward in a direction perpendicular to the inlet;
The inlet portion is configured in a tangential direction to the cylindrical portion,
It relates to a hydrocyclone comprising an arc-shaped part that is rolled into the hydrocyclone to form a rotational flow inside the hydrocyclone.

Description

Hydro Cyclone and Wastewater Treatment System Using the Same

The present invention relates to an improved hydrocyclone and a wastewater treatment apparatus using the same.

The particle size (particle size) of particulate matter contained in wastewater such as construction wastewater, factory wastewater, household sewage, sewage, and turbid water has a wide particle size range and specific gravity from 1 μm or less, the colloidal size, to 10,000 μm. Particulate matter in such wastewater can be removed through gravity sedimentation, coagulation sedimentation, flotation separation, filtration, and the like.

Gravity precipitation is the most common method, but it is applied only to particles with a specific gravity greater than 1, so there is a limit to the removal of colloidal particles. Coagulation precipitation is possible by gravity precipitation by forming heavy lumps (hereafter floc) using chemicals up to colloidal particles with specific gravity less than 1.

Flotation separation is effective only for removing particulate matter with a specific gravity less than 1 by attaching microbubbles to particles with specific gravity equal to or smaller than 1, increasing buoyancy and removing them. Filtration is the most effective technique for removing particulate matter, but a backwashing process is required for reuse of the filter media, and replacement costs are high when the filter media is clogged, damaged or degraded.

As a method for efficiently treating wastewater based on these characteristics, a coagulant precipitation method using chemicals is being used in various industrial fields.

The coagulation precipitation method consists of coagulation, flocculation, and sedimentation. Coagulation is the process of diffusing the drug so that wastewater and drugs can be mixed smoothly, and coagulation is the process of forming flocs so that particulate matter in wastewater and the drug diffused are combined to cause gravity precipitation.

In the coagulation precipitation method, coagulation, which diffuses the drug, is achieved by rapid stirring, and coagulation, which forms flocs, is performed by slow stirring. The formed flocs are precipitated and separated into residue (sludge) and treated water (supernatant).

In the case of water treatment and advanced sewage treatment, coagulation sedimentation method is used for the purpose of removing impurities as much as possible by adding chemicals to relatively clean water (concentration of suspended substances 10 mg/L or less) compared to the above-mentioned wastewater. Therefore, after rapid stirring, slow stirring to grow flocs is essential, and flocculation aids or polymers are additionally used because the flocs should be grown to the maximum to enable precipitation.

On the other hand, in the case of high-concentration wastewater, the particle size distribution varies because the suspended matter concentration is greater than 100 mg/L. As the number of collisions and bonding between the drug and particles increases, particles with a specific gravity less than 1 may defect with larger particles to form heavy flocs. Therefore, flocs are formed only by injecting chemicals and rapid stirring, and gravity precipitation is possible. In the coagulation sedimentation method for high-concentration wastewater treatment, the role of rapid stirring is the most important.

However, the conventional cyclone 200 has been limited in rapid stirring.

The conventional cyclone will be described in detail as shown in FIGS. 5A to 8 .

As shown in FIGS. 5A, 5B and 6 , the inlet 210 for introducing wastewater is configured to directly enter the cylindrical upper part 245 of the conventional cyclone 200 .

That is, it ends at the point where the inlet inner inner side surface 212 meets the cylindrical upper portion 245 .

The inlet inner and outer surface 214 refers to a surface corresponding to the outer side of the cylindrical upper portion 245 .

In the upper part of the cylindrical part, the outlet 220 is formed in a direction perpendicular to the inlet, and the lower outlet 230 may be configured by selecting the configuration according to the case.

A conventional hydrocyclone 200 is constituted by a cylindrical portion 240 and a conical portion 250 .

7 is a diagram showing the result of performing computational fluid dynamics (CFD).

In this way, in FIG. 7, the velocity of wastewater flowing in at a flow of 1 m/s ends the moment it enters the upper part of the cylinder, and immediately decreases to a speed of 0.7 to 0.9 m/s, and then immediately decreases to 0.1 to 0.3 m/s at the midpoint of the upper part of the cylinder. speed drops rapidly Therefore, there is a limit to rapid stirring.

The efficiency of the conventional hydrocyclone 200 is a view showing the suspended solids (Suspended Solids; hereinafter referred to as SS.) and the removal efficiency and the suspended solids flowing out from the outlet 220, as shown in FIG.

In the graph, the suspended matter concentration is indicated in mg/L on the left, and the suspended matter removal efficiency is indicated by the ratio on the right.

The amount of suspended matter flowing in is about 900-1200 mg/L in 1 hour and 24 minutes, as shown in the red graph,

The removal efficiency of suspended matter corresponds to the black graph and has a removal efficiency of about 80%.

In contrast, it can be seen that the amount of suspended matter leaking out is about 100 to 400 mg/L.

It can be seen that there is still a lot of suspended matter flowing out.

This is that the effect is significantly reduced when compared with FIG. 4 when the present invention is applied.

The present invention was invented to solve such a problem.

Korean Intellectual Property Office Registered Patent Publication 10-1132903 (2012.04.03) Korean Intellectual Property Office Registered Patent Publication No. 10-1614651 (2016.04.22)

The first task is to solve the task of providing a hydrocyclone that enables rapid stirring without power.

The second task is to solve the problem of providing a wastewater treatment apparatus using a hydrocyclone rapid agglomeration apparatus by using the rotational flow (vortex) generated by the structural characteristics of the hydrocyclone in the rapid stirring process for the flocculation reaction.

In order to solve the above problems, it has the following configuration.

In the hydrocyclone consisting of a cylindrical portion having a cylindrical shape and a conical portion below the cylindrical portion,

An outlet configured to be directed upward in a direction perpendicular to the inlet formed in the cylindrical portion constitutes.

The inlet part is configured in a tangential direction to the cylindrical part, but constitutes a hydrocyclone having an arc-shaped part that is rolled and entered to form a rotational flow inside the hydrocyclone.

Here, it is preferable that the arc-shaped end portion is continuously configured up to a line crossing the diameter of the cylindrical portion, which is a line parallel to the proceeding direction of the inlet portion.

Here, the diameter of the inlet portion preferably has a configuration corresponding to 1/5 of the diameter of the cylindrical portion.

Here, the inner length of the outlet portion preferably has a configuration corresponding to the length of the diameter of the inlet portion from the inner end of the upper cylindrical portion to the lower portion.

Here, the configuration of the end of the arc-shaped part is an arc from the arc-shaped upper junction where the inner inner surface of the inlet of the inlet is connected with the upper part of the cylindrical part configured on the upper part of the cylindrical part to the right angle direction, which is the direction in which the wastewater of the inlet flows in. However, it is preferable to have a configuration such that the thickness (t) of the upper part of the cylindrical part is gradually reduced at the intersection of the arc-shaped upper part so that the inner side surface of the inlet part ends in a right angle direction.

Here, it is preferable to additionally configure a lower discharge part at the lower end of the conical part.

The inside of the inlet is composed of an inlet inner inner surface 112 and an inlet outer inner surface 112a, and the inlet outer inner surface 112a is preferably configured to enter in a tangential direction of the cylindrical portion.

It is preferable to configure a wastewater treatment device using the hydrocyclone.

The first effect is to have the effect of providing a hydrocyclone that enables rapid stirring without power.

A second effect is to provide a wastewater treatment apparatus using a hydrocyclone rapid agglomeration apparatus as a rotational flow (vortex) generated due to the structural characteristics of the hydrocyclone is used in the rapid stirring process for the agglomeration reaction.

Figure 1a is a view showing a perspective view of the cyclone of the present invention.
Fig. 1b is a view showing an upper cross-sectional view of Fig. 1a.
FIG. 2 is a cross-sectional view showing a portion where the inlet and the cylindrical upper part meet after removing the outlet in FIG. 1b.
Figure 3a is a diagram showing the flow flow inside the hydrocyclone by allowing the inflow water to be introduced at 1 m/s into the cyclone constructed according to the present invention.
Figure 3b is a view showing the overall flow flow inside the hydrocyclone.
4 is a graph showing the purification of wastewater using the present invention.
Figure 5a is a view showing a perspective view of a cyclone of the background art.
Fig. 5b is a view showing an upper cross-sectional view of Fig. 1a.
6 is a cross-sectional view showing a portion where the inlet and the cylindrical upper part meet after removing the outlet in FIG. 5b.
7 is a diagram showing the flow flow inside the hydrocyclone by allowing the influent to flow at 1 m/s to the cyclone constructed as a background art.
8 is a graph showing the purification of wastewater using the background art.

A cyclone is widely used in various fields such as gas purification, combustion, spraying, and powder classification, and is used for solid/liquid separation. Among them, a cyclone specially invented for liquid treatment is called a hydraulic cyclone or hydrocyclone (hydrocyclone; 100).

The hydrocyclone 100 is composed of a cylindrical section 140 and a conical section 150, as shown in Figure 1a, and an inlet (feed; 110) and an outlet ( It consists of an overflow; 120) and an underflow (130). Figure 3b schematically shows the fluid and particle flow form inside the hydrocyclone (100).

The hydrocyclone 100 does not require a separate driving force, so it is easy to maintain, and the processing time is short and the processing flow rate can be increased indefinitely by using a bundle-type structure, which is being used in various industrial fields. In water treatment, it is limited to particle separation or solid-liquid separation, and there is no domestic or foreign technology applying the hydrocyclone 100 as a high-speed coagulation device for wastewater treatment.

The present invention uses a rotational flow (vortex) generated by the structural characteristics of the hydrocyclone 100 in a rapid stirring process for agglomeration reaction, and provides a wastewater treatment apparatus and technology using the hydrocyclone 100 rapid agglomeration apparatus. for that purpose

The present invention uses the rotational flow (vortex) generated in the hydrocyclone 100 for rapid agitation for wastewater treatment. In order to effectively achieve this, the shape of the part where the wastewater flows into the hydrocyclone 100 is optimal condition. It should be designed so that the generation of rotational flow can be maximized.

The existing hydrocyclone 200 is a method in which wastewater flows tangentially to the cylinder (body) as shown in Fig. 5b. (110) to adopt a method of entering into a rolling so as to form a rotational flow.

The technology of the invention will be described in detail with reference to FIGS. 1a to 2 as follows.

It has a cylindrical portion 140 having a cylindrical shape.

The configuration of the hydrocyclone 100 composed of the conical part 150 under the cylindrical part 140 is the same as that of the conventional hydrocyclone.

The inlet part 110 is formed in the cylindrical part 140 .

The outlet portion 120 is configured to be directed upward in a direction perpendicular to the inlet portion 110, but the length of the inner portion of the outlet portion 120 is the same as the diameter of the inlet portion 110 or the length of one side of the rectangle. Or it may be configured to extend downward The inlet 110 is possible to use a square or cylindrical pipe.

The inlet 110 is configured in a tangential direction to the cylindrical portion 140,

The hydrocyclone 100 is constituted by an arc-shaped part (f) that is rolled and entered to form a rotational flow inside the hydrocyclone 100. This configuration dramatically increases the speed of the rotational flow.

The arc-shaped end portion (b) is configured to be continuously configured up to a line crossing the diameter of the cylindrical portion 140 which is a parallel line with the moving direction of the inlet portion 110 .

When the diameter of the inlet portion 110 corresponds to 1/5 of the inner diameter D of the cylindrical portion 140, the processing efficiency is highest.

Although it is expressed as the inlet diameter in the claims, it means the diameter in the case of a cylindrical tube and the length of one side in the case of a square pipe. That is, in the present invention, the term "diameter" is used in the same sense as the length of one side.

The inner length of the outlet portion 120 is configured to correspond to the length of the diameter of the inlet portion 110 from the inner end of the cylindrical upper portion 145 to the lower portion, so that the wastewater flowing in from the inlet portion 110 is directly upper It is configured not to go out to the outlet 120 of the.

In the present invention, the inlet 110 used a square tube. In this case, it is defined by the length of one side.

The configuration of the arc-shaped end portion (b) is the arc-shaped upper junction ( An arc is formed from a) to a right angle direction, which is the direction in which the wastewater of the inflow part 110 flows, and the thickness t of the cylindrical upper part 145 at the arc-shaped upper intersection point (a) is gradually smaller. It is to maintain the flow rate of the inlet 110 inside the hydrocyclone 100 for the longest time to configure the inlet inner inner side surface 112 to end in a right angle direction.

The inlet inner/outer side surface 114 is connected to the inner side surface having an outer diameter.

The intersection of the inlet inner and outer side surfaces 114 in the immediate upper part of the arc-shaped upper junction (a) is called an external mirror junction (c). It has a large outer diameter of the cylindrical shape along the inner and outer side surfaces 114 of the inlet passing through the outer circumferential intersection (c). In this case, as shown in the drawing, L2 corresponds to L2 = 1.2D + 3t. As shown in Figure 2, a large-diameter portion is constituted. ) to the dotted line shows the virtual large outer diameter portion 144, which is a virtual cylindrical portion.

At the lower intersection point (d), it has a connection point (e) that intersects the inlet portion by forming the outer neck portion (146).

The bore (D), which is the inner diameter of the cylindrical upper cyclone, forms a cylindrical part in a clockwise direction from the lower intersection point (d), and the intersection with the inlet part is called the connection point (e), and the arc-shaped upper intersection point (a) The thickness (t) of the cylindrical part gradually becomes thinner from the arc-shaped upper intersection point to the right angle direction in the clockwise direction to form an arc shape so as to reach the end point of the arc shape.

This is an important element constituting the cyclone of the present invention.

Of course, it is included in the scope of the claims of the present invention to make modifications in the illustrated and described parts to configure the entire wastewater to be wound around it.

The inside of the inlet is composed of an inlet inner inner surface 112 and an inlet inner outer surface 114, and the inlet inner inner surface 112 is preferably configured to enter in a tangential direction to the cylindrical portion 140. .

The contact point in the tangential direction is a point as much as the thickness of the arc-shaped upper intersection point (a).

Of course, the effect can be exerted even if the inlet inner inner side surface 112 enters in the tangential direction of the cylindrical portion 140 .

The contact point in the tangential direction may be a point spaced apart by the thickness of the arc-shaped upper intersection (a) or the thickness of the directly lower portion of the arc-shaped upper intersection (a).

In the present invention, the tangential direction enters the cylindrical portion, but at the intersection where the tangent line is formed, the thickness of the cylindrical portion is gradually formed in the form of a thin film in the shape of an arc in the right angle direction to constitute the arc-shaped end portion (b).

The diameter of L2, which is the large outer diameter, corresponds to the diameter of L2 until the lower intersection point (d), which is an intersection with an extension line extending through the center of the diameter through the outer diameter upper intersection point (c).

A lower discharge unit 130 is additionally configured at the lower end of the conical unit 150 so that the outflow water is discharged to the lower side may be optionally configured.

The diameter of the outlet is 0.3D, the diameter of the lower outlet is 0.1D, and the length of the cone is 3D to maximize the effect.

L1 is the length obtained by subtracting the top and bottom thickness 2t from L2, and is the inner diameter of the outer circle.

The hydrocyclone 100 described above is used as a wastewater treatment device.

The present invention uses the rotational flow (vortex) generated by the structural characteristics of the hydrocyclone 100 in the rapid stirring process for the agglomeration reaction. for that purpose

3A to 4 correspond to the drawings and experimental data showing the effects of the present invention.

Figure 3a is a diagram showing the result of performing computational fluid dynamics (CFD).

In order to compare the rotational flow generation of the hydrocyclone 200 of the prior art and the hydrocyclone 100 of the present invention, a cross section of the inlet 110 was designed and computational fluid dynamics (CFD) was performed. As a result of analyzing the inlet portion 110 diameter and the hydrocyclone 100 inner diameter of the conventional hydrocyclone and the hydrocyclone of the present invention as the same, and the inflow flow rate is 1.0 m/sec, the present invention as shown in FIG. 3 Compared with the prior art hydrocyclone 100 of FIG. 7, the rotational flow was generated more strongly.

Because of this configuration, in FIG. 3, the velocity of wastewater flowing in at a flow of 1 m/s enters the cylindrical upper part 145, passes the arc-shaped part f, and continues up to about 3/5 rotations inside the cylindrical part 145. .

After that, it is reduced to a speed of 0.7 to 0.9 m/s, and maintains a speed of 0.4 to 0.6 m/s until one rotation inside the cylindrical upper part 145.

On the inner surface, which is the other surface of the cylindrical portion 140, most of the speed is maintained at a speed of 0.1 to 0.3 m/s. As such, rapid stirring is superior to the prior art.

Referring to FIG. 4, it is as follows.

The efficiency of the hydrocyclone 100 of the present invention is a view showing the suspended solids (Suspended Solids; hereinafter referred to as SS.) and the removal efficiency and the suspended solids flowing out from the outlet 120, as shown in FIG.

In the graph, the suspended matter concentration is expressed in mg/L on the left, and the suspended matter removal efficiency (%) is indicated by the ratio on the right.

The amount of suspended matter introduced in the red graph is about 900 to 1200 mg/L in the prior art for 1 hour and 24 minutes, whereas the amount of suspended matter of the present invention is about 1150 to 1300 mg/L. It was tested in more states.

The removal efficiency of suspended matter corresponds to the black graph and has a removal efficiency of about 90%.

The prior art has a removal efficiency of about 80%.

In contrast, the amount of suspended matter flowing out is about 30 mg/L. Compared to that of about 100 to 400 mg/L in the prior art, if compared to the amount of suspended matter flowing out than in the prior art, it will bring about 3 to 13 times the effect.

It can be seen that the amount of suspended matter flowing out is remarkably reduced despite the inflow of more suspended matter than in the prior art.

This has a significantly higher effect compared to FIG. 8 when the prior invention is applied.

The terms or words used in the present specification and claims should not be construed as being limited to their ordinary or dictionary meanings, and the inventor may properly define the concept of the term in order to best describe his invention. Based on the principle that there is, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention, and do not represent all of the technical spirit of the present invention, so at the time of the present application, they can be replaced It should be understood that various equivalents and modifications may exist.

a: arc-shaped upper junction b: arc-shaped lower end c: external circumferential upper junction d: lower junction
e: connection point f: arc
100: hydrocyclone 110: inlet 112:: inlet inner inner side
112a: inlet external internal side
114: inlet inner and outer side 120: outlet 130: lower outlet
140: Cylindrical part 142: External diameter part 144: Virtual external diameter part 145: Cylindrical part upper part
146: marginal part 150: cone part
200: conventional hydrocyclone 210: inlet 212:: inlet inside inner side
214: inlet inner and outer side 220: outlet 230: lower outlet
240: Cylindrical part 245: Cylindrical part upper part 250: Conical part

Claims (8)

A cylindrical part having a cylindrical shape, and
In the hydrocyclone composed of a conical part under the cylindrical part,
But configuring the inlet to the cylindrical portion,
The inside of the inlet is composed of an inlet inner inner surface 112 and an inlet inner outer surface 114, and the inlet inner inner surface 112 is configured to enter in the tangential direction of the cylindrical portion,
Configure the outlet to face upward in a direction perpendicular to the inlet,
The inlet portion is configured in a tangential direction to the cylindrical portion,
It constitutes an arc-shaped part to be rolled in to form a rotational flow inside the hydrocyclone,
The arc-shaped end portion is continuously configured up to a line crossing the diameter of the cylindrical portion, which is a line parallel to the proceeding direction of the inlet portion,
The configuration of the end of the arc-shaped part is a right angle in which the wastewater of the inlet flows in at the arc-shaped upper junction (a) where the inner inner surface 112 of the inlet of the inlet is connected to the upper part of the cylindrical part configured on the upper part of the cylindrical part. The arc is formed up to the direction, but at the arc-shaped upper intersection (a), the thickness (t) of the upper cylindrical portion is gradually reduced so that the inlet inner inner side surface 112 ends in a right angle direction. Hydrocyclone, characterized in that . delete The hydrocyclone according to claim 1, wherein a diameter of the inlet portion corresponds to 1/5 of the diameter of the cylindrical portion. The hydrocyclone according to claim 1, wherein the inner length of the outlet portion corresponds to the length of the diameter of the inlet portion from the inner end of the upper cylindrical portion to the lower portion. delete According to claim 1, wherein the lower discharge portion is additionally configured at the lower end of the conical portion, and the inlet inner and outer side surfaces 114 are the intersections at the upper portion of the arc-shaped upper intersection (a). ,
The diameter (L2) of the large diameter of the outer diameter portion 142 having the large outer diameter of the cylindrical portion along the inner and outer side surfaces 114 of the inlet portion passing through the outer diameter portion intersection (c) is the small inner diameter (D) and the thickness of the cylindrical portion The relationship with t consists of L2=1.2D + 3t,
Hydrocyclone, characterized in that it is configured to have a virtual large outer diameter portion 144 that is a virtual cylindrical portion from the lower intersection point (d) of the outer diameter portion 142 to the outer diameter portion intersection point (c) in a clockwise direction. delete A wastewater treatment apparatus using the hydrocyclone of any one of claims 1, 3, 4 and 6.

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