KR101211654B1 - Floatation plant - Google Patents

Abstract

PURPOSE: A solid-liquid floatation apparatus is provided to separate solid parts of high specific gravities by improving the efficiency of a solid-liquid separation. CONSTITUTION: A solid-liquid floatation apparatus includes a floatation main body(110), a scum removing unit(120), and a feed water flotation inducing unit(130). Floc from feed water is coagulated through the coagulation reactor and is attached on microbubbles in the flotation main body such that the microbubbles with the floc float on the surface of water. The feed water flotation inducing unit uses a hydrocyclone method and includes a cyclone main body(131) and a flotation inducing guide(132). The cyclone main body includes a conical part(131a) and a cylindrical part(131b). [Reference numerals] (AA) Introducing feed water; (BB) Treated water; (CC) Feed water; (DD) Pressurized water

Description

Solid-liquid Flotation Separator

The present invention relates to a solid-liquid flotation separator, and more particularly, it is possible to improve the solid-liquid separation efficiency and to shorten the residence time of the flocculation reaction tank with respect to the inflow water, thereby minimizing the capacity of the flocculation reaction tank. The present invention relates to a solid-liquid flotation separator capable of separating solids having a high specific gravity.

The solid-liquid flotation device is a device for separating solids and liquids, and is generally applied to water purification or sewage treatment. That is, the solid-liquid flotation device separates the suspended solids in the water or forms a floc (solid sludge) through the flocculant to form a solid-liquid separation.

Looking at the prior art, the inflow of the coagulation through the coagulation reaction tank is introduced to one side of the solid-liquid flotation separator, the microbubble from the microbubble generator to the other side of the solid-liquid flotation separator. Thus, when the flocks of the inflow water aggregated in the micro-bubble contact and cling to the surface together with the micro-bubble scum remover is installed on the top to remove it.

However, in the prior art, since the inflow water and the microbubbles are supplied through separate lines as shown in FIG. 1, the contact between the microbubbles and the flocs in the inflow water is not smooth, so that the flocs are not easily floated, and the liquid-liquid separation efficiency is lowered. .

In particular, in the case of the prior art, after the inflow water passes through the inflow stage of the solid-liquid flotation device, the inflow pressure drops and falls in the DIRECTION OF FLOW of FIG. 1, thereby reducing the chance of contact with the microbubbles. Therefore, there is a problem in that the solid-liquid separation efficiency falls.

If the solid-liquid separation efficiency is inevitably low, the residence time of the coagulation reaction tank must be maintained for a long time, and the capacity of the coagulation reaction tank is inevitably increased, and in the case of a solid having a specific gravity, the separation is impossible. Since there is a problem, an efficient structural improvement is required.

Korean Patent Office Application No. 20-2001-0031768

An object of the present invention can improve the solid-liquid separation efficiency can shorten the residence time of the flocculation reaction tank to the inflow source water to minimize the capacity of the flocculation reaction tank, and also solid-liquid flotation that can separate the high specific gravity solids It is to provide a separation device.

The object of the present invention is to provide a flotation separation tank body for forming a place where the floc of the inflow water in which the flocculation reaction has occurred through the flocculation reaction tank adheres to the micro bubbles and floats to the surface together with the micro bubbles; A scum remover disposed on an upper portion of the floating separator body and removing a scum formed by mixing of the floc and foreign matter floating on the surface of the floating separator body; And an influent floatation induction device coupled to one side of the floatation separator body and causing the inflow to float in a hydrocyclone manner so that the inflow water is floated onto the surface of the floatation vessel body. Achieved by a flotation device.

The inflow water induction apparatus, the cyclone body having a conical portion gradually decreasing in diameter toward the lower end, and a cylindrical portion formed with the same diameter from the upper end to the upper portion of the cone; And a lower end portion is disposed in the cyclone body, and the upper end portion is extended to an upper region of the cyclone body to include an induction guide for guiding the inflow of the influent.

The floating guide may be extended to a length of 1/2 or more of the separation tank body.

The inflow water induction apparatus is coupled to the vertex of the cone portion is provided in the apex exposed to the frame supporting the float separation vessel body from the bottom, the sludge drawn to draw the sludge dropped toward the apex relatively large particles It may further include wealth.

An inflow water inflow pipe connected to a distribution tank disposed between the agglomeration reaction tank and the floating separation tank main body and introducing the inflow water to one side of the cylindrical portion; And a pressurized water supply unit supplying pressurized water to a central region in the cylindrical portion to generate the micro bubbles.

The pressurized water supply unit may be disposed at one side of the floating separator main body, and a circulation water storage tank configured to store a portion of the treated water from which the scum is removed; A gas-liquid mixing unit in which air and the circulating water are mixed to form the micro bubbles; A circulation water pump for pumping the circulation water in the circulation water storage tank to the gas-liquid mixing unit; A compressor for providing the air to the gas-liquid mixing unit; A pressurized tank connected to the gas-liquid mixing unit and pressurizing the air-mixed circulating water mixed with the air in the gas-liquid mixing unit; And a pressurized water line having one end connected to the pressurized tank and the other end disposed at a central region in the cylindrical portion of the cyclone body.

According to the present invention, it is possible to improve the solid-liquid separation efficiency to shorten the residence time of the flocculation reaction tank to the inflow source water to minimize the capacity of the flocculation reaction tank, and also has the effect of separating solids with a high specific gravity. .

1 is a block diagram of a solid-liquid flotation device according to the prior art,
2 is a block diagram of a hexahedral solid-liquid separation device according to a first embodiment of the present invention,
3 is an enlarged view of the inflow water induction apparatus shown in FIG.
Figure 4 is a block diagram of a circular solid-liquid separation device according to a second embodiment of the present invention,
5 is a schematic configuration diagram of a solid-liquid floating separator according to a third embodiment of the present invention;
FIG. 6 is a plan view of FIG. 5.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention. In the description of the embodiments, the same reference numerals are assigned to the same components.

2 is a block diagram of a hexahedral solid-liquid separation device according to a first embodiment of the present invention, Figure 3 is an enlarged view of the influent flotation guide device shown in FIG.

As shown in these figures, the solid-liquid flotation separator of the present embodiment is a hexahedron, and includes a flotation vessel body 110, a scum remover 120, and an influent flotation induction device 130.

The flotation tank body 110 forms a place where the floc of the inflow water in which the flocculation reaction occurs is attached to the microbubbles and floats to the surface together with the microbubbles.

One side of the floating separation tank main body 110 is provided with an agglomeration reaction tank 111 to introduce the incoming water. The flocculation reaction tank 111 is a place for forming the dissolved substance in the influent water into floc (solid sludge) through the flocculant.

As will be described later, the solid-liquid flotation separator of the present embodiment can improve the solid-liquid separation efficiency than the conventional, it is possible to significantly shorten the residence time of the flocculation reaction tank 111 with respect to the incoming water than conventional. Therefore, it is possible to minimize the capacity of the flocculation reaction tank 111, as well as to separate the high specific gravity solids.

At one side of the coagulation reaction tank 111, a coagulation reaction occurs and a distribution tank 112 for distributing the inflow water to be introduced into the floating separation tank body 110 is disposed.

On the other side of the distribution tank 112 on the basis of the float separation tank body 110, a treated water discharge part 113 through which the treated water is discharged is provided. The treatment water guide plate 114 is disposed around the treatment water discharge unit 113 to guide the treatment water to the treatment water discharge unit 113.

The scum remover 120 is disposed on an upper portion of the floating separator main body 110 and serves to remove a scum that is formed by mixing a floc and foreign matter floating on the surface of the floating separator main body 110.

The scum remover 120 having a plurality of scum removal plates 121 is rotated to one side to remove the scum floating on the surface of the floating separator main body 110 to be transferred to the scum channel 122.

On the other hand, the inflow water induction device 130 is coupled to one side of the floating separation tank body 110, unlike the conventional inflow water inlet to the surface of the floating separation tank body 110 in a hydro cyclone method Injury role.

Inflow water induction device 130 may be arranged in one or a plurality of floating tank body 110. In the embodiment shown in Figure 2, one influent floating guide device 130 is installed.

Hydrocyclone influent flotation device 130 uses a principle that a low pressure state is generated in the center of swirl flow when generating swirl flow (water) of inflow water, and in particular, the volume or density of the floc in the inflow water is small. It serves to quickly rise to the surface of the float separation tank body (110).

Unlike the conventional flotation separation tank, when the hydrocyclone inflow flotation device 130 is applied, the solid-liquid separation efficiency may be much higher because it is possible to remove a solid having a specific gravity, for example, a certain size or more of the flocs.

The hydrocyclone inflow floating apparatus 130 having such a role is formed in the same diameter from the upper end of the cone portion 131a and the upper end of the cone portion 131a, the diameter of which gradually decreases toward the lower end portion. Cyclone body 131 having a cylindrical portion 131b, and the lower end is disposed in the cyclone body 131 and the upper end is extended to the upper region of the cyclone body 131 to guide the induction of the inlet guide 132 ).

The supplied influent causes swirling flow in the cyclone body 131 according to the hydrocyclone principle. At this time, the flocks (sludges) having large size and density sink and fall down while hitting the inner wall of the cone portion 131a while turning. And small-density flocs or liquids (influent itself) can be raised while turning in the center. As the pressurized water is supplied from the central region of the cylindrical portion 131b to the upper portion of the rising inflow water, the inflow water sticks to the microbubbles included in the supplied pressurized water and quickly reaches the surface of the floating separator main body 110. You may be injured.

The floating induction guide 132 extends upward to facilitate contact with the microbubbles and the inflow water, and the inflow of the inflow water mixed with the microbubbles is induced to be discharged from the upper portion of the floating separation vessel body 110 as much as possible. The guide 132 may extend at least 1/2 or more lengths of the flotation tank body 110.

The apex 133 is coupled to the vertex region of the cone portion 131a. The apex 133 is provided with a sludge drawing part 134 that draws sludge that has a relatively large particle and falls toward the apex 133. In other words, sludge having a large size and density deposited on the apex 133, which is a vertex portion of the lower end of the cyclone body 131, may be drawn through the sludge drawing part 134 based on the hydrocyclone principle.

For such sludge drawing, a portion of the cyclone body 131 is preferably exposed to the lower portion of the floatation tank body 110. For example, it is preferable that at least as much as the sludge drawing part 134 is exposed to the lower part of the frame P supporting the floating separation tank body 110 from the bottom for the sludge drawing.

On the other hand, the solid-liquid floating separator of the present embodiment, the inflow water inlet pipe 150 for introducing the inflow water to one side in the cylindrical portion 131b of the cyclone body 131, and the cylindrical portion of the cyclone body 131 to generate micro bubbles The pressurized water supply part 160 which supplies pressurized water to the center area | region in 131b is provided.

One end of the inflow water inlet pipe 150 is connected to the distribution tank 112, and the other end thereof is disposed at one side in the cylindrical portion 131b of the cyclone body 131.

The pressurized water supply unit 160 is disposed at one side of the floating separation tank main body 110, and the circulation water storage tank 161 in which a part of the treated water in which scum is removed is stored, and air and the circulation water to form micro bubbles. The gas-liquid mixing unit 162 to be mixed with the water, the circulating water pump 163 for pumping the circulating water in the circulation water storage tank 161 to the gas-liquid mixing unit 162, and a compressor for providing air to the gas-liquid mixing unit 161 ( 164 and the gas-liquid mixing unit 161, the pressurized tank 165 for pressurizing the air mixed circulation water mixed with air in the gas-liquid mixing unit 161, one end is connected to the pressurized tank 165, The other end includes a pressurized water line 166 disposed in a central region in the cylindrical portion 131b of the cyclone body 131. The air mixed circulation water pressurized by the pressurization tank 165 is the pressurized water mentioned above.

As such, when the mixed air mixed with air through the gas-liquid mixing unit 162 is pressurized with a strong pressure and provided as the inflow water in the floating separation tank body 110, the microbubbles may be made in large quantities. By forming a layer, the floc is in contact with the floc in the floating influent to float the floc onto the surface of the flotation vessel body 110.

In particular, the other end of the influent inlet pipe 150 is disposed in the region of the cylindrical portion 131b of the cyclone body 131, and the pressurized water line 166 of the cyclone body 131 is different from the conventional art. As the cylindrical portion 131b is disposed in the region, the inflow water and the pressurized water flow into the cyclone body 131 at the same time, thereby increasing the contact efficiency thereof.

Hereinafter, the operation of the solid-liquid floating separator of the present embodiment will be described.

The inflow water is agglomeration reaction occurs through the agglomeration reaction tank 111, and then the inflow water is introduced into one side in the cylindrical portion 131b of the cyclone body 131 via the distribution tank 112.

The inflow water flowing into the cyclone body 131 is floated by the hydrocyclone principle. In this case, the inflow water and the microbubbles are introduced at high efficiency by injecting the microbubbles of pressurized water into the central region of the cylindrical portion 131b of the cyclone body 131. After contacting, the surface of the floatation tank body 110 is floated.

The scum of the flocks and other foreign matters floating on the surface of the flotation tank body 110 is removed through the scum remover 120, and the scum removal completed is discharged through the treated water discharge part 113. Some treated water is reused as circulating water to generate microbubbles.

In addition, the solids having a large volume and specific gravity precipitated in the apex 133, which is the vertex of the flotation tank body 110, are drawn out through the sludge drawing part 134.

According to this embodiment having such a structure and action, it is possible to improve the solid-liquid separation efficiency can shorten the residence time of the flocculation reaction tank 111 with respect to the incoming water can minimize the capacity of the flocculation reaction tank (111). In addition, high solids, which are specific gravity, can be separated.

Figure 4 is a block diagram of a circular solid-liquid floating separator according to a second embodiment of the present invention.

In the case of Figure 4, the solid-liquid flotation separator of the present embodiment is circular, except that one hydrocyclone inflow flotation guide device 130 is applied to the central region of the flotation tank body 210 is all The configuration is the same as in the above-described embodiment.

FIG. 5 is a schematic configuration diagram of a solid-liquid flotation separator according to a third embodiment of the present invention, and FIG. 6 is a plan view of FIG.

In the present embodiment, a plurality of hydrocyclone inflow floating induction apparatus 130 is applied to the example is presented.

When the capacity of the float separator main body 310 is large, as shown in FIG. 5, a plurality of influent flotation induction devices 130 may be used, except that a plurality of influent flotation induction devices 130 are disposed. And functions are the same as in the above-described embodiment.

However, although optional, a plurality of inflow water discharge pipes 360 may be disposed around the inflow water inflow pipe 350 in the floating separation tank body 310. Influent water discharge pipe 360 may be provided with a plurality of through holes 361 as enlarged in FIG.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

110: floating separator main body 111: flocculation reaction tank
112: distribution tank 113: treated water discharge
114: treated water guide plate 120: scum eliminator
121: scum removal plate 122: scum channel
130: influent floating guide device 131: cyclone body
131a: cone portion 131b: cylinder portion
132: guide to injury 133: Apex
134: sludge drawing unit 150: influent inlet pipe
160: pressurized water supply unit

Claims (6)

Floating separation tank body to form a place where the floc of the inflow water in which the flocculation reaction has occurred through the flocculation reaction to the microbubble to rise to the surface with the microbubble;
A scum remover disposed on an upper portion of the floating separator body and removing a scum formed by mixing of the floc and foreign matter floating on the surface of the floating separator body; And
It is coupled to one side of the flotation tank body, and includes an influent flotation induction device for floating the inflow water in a hydro cyclone manner so that the inflow water is floated to the surface of the flotation tank body,
The influent flotation device,
A cyclone body having a conical portion that gradually decreases in diameter toward the lower end, and a cylindrical portion having the same diameter toward the upper portion from the upper end of the conical portion; And
And a lower end portion disposed in the cyclone body and an upper end portion extending to an upper region of the cyclone body to guide a floating guide.
delete The method of claim 1,
The flotation induction guide is a solid-liquid flotation separator, characterized in that extending to more than half the length of the separation tank body.
The method of claim 1,
The influent flotation device,
It is coupled to the vertex region of the cone portion is provided in the apex exposed to the frame supporting the floating separation tank body from the bottom, characterized in that it further comprises a sludge drawing for drawing the sludge dropped toward the apex relatively large particles Solid-liquid flotation device.
The method of claim 1,
An inflow water inflow pipe connected to a distribution tank disposed between the agglomeration reaction tank and the floating separation tank main body and introducing the inflow water to one side of the cylindrical portion; And
And a pressurized water supply unit for supplying pressurized water to a central region in the cylindrical portion for generating the microbubbles.
The method of claim 5,
The pressurized water supply unit,
A circulating water storage tank disposed at one side of the floating separation tank body and storing some of the treated water from which the scum is removed;
A gas-liquid mixing unit in which air and the circulating water are mixed to form the micro bubbles;
A circulation water pump for pumping the circulation water in the circulation water storage tank to the gas-liquid mixing unit;
A compressor for providing the air to the gas-liquid mixing unit;
A pressurized tank connected to the gas-liquid mixing unit and pressurizing the air-mixed circulating water mixed with the air in the gas-liquid mixing unit; And
And a pressurized water line having one end connected to the pressurized tank and the other end disposed at a central region within the cylindrical portion of the cyclone body.

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