KR101077248B1 - Solid and liquid separator using micro bubble - Google Patents

Abstract

The present invention relates to a microbubble floating solid-liquid separation device by low vacuum mixing, and more specifically, to a cohesive agent and a fine bubble at the same time to livestock manure or sewage water to increase the cohesive efficiency to fine-separation by low-vacuum mixing It relates to a bubble floating solid-liquid separation device.
The microbubble floating solid-liquid separator by the low vacuum mixing of the present invention is a multi-role cyclone for separating sedimentable contaminants in the water to be treated by turning the water to be treated, including livestock manure or sewage, and discharge from the multi-cyclone And a coagulation reaction unit in which coagulant and air are simultaneously introduced into the water to be treated and stirred, and a solid-liquid separation unit for solid-liquid separation of the water to be treated via the coagulation reaction unit into a supernatant and sludge.

Description

Floating solid-liquid separator for microbubbles by low vacuum mixing {Solid and liquid separator using micro bubble}

The present invention relates to a microbubble floating solid-liquid separation device by low vacuum mixing, and more specifically, to a cohesive agent and a fine bubble at the same time to livestock manure or sewage water to increase the cohesive efficiency to fine-separation by low-vacuum mixing It relates to a bubble floating solid-liquid separation device.

Most water treatment facilities for treating livestock manure or sewage are equipped with at least one flotation tank to effectively remove contaminants such as sludge and SS (floating turbidity) introduced with raw water. According to the flat shape of the tank and the method of removing the sludge, it is classified into a circular floating tank, a scraper-type rectangular floating tank, and an inclined plate type rectangular floating tank.

In general, in order to precipitate the suspension and separate the flotation liquid by flotation, a process of homogeneously mixing the flocculant and the microbubbles with the suspension to make the flotation flocculate the suspension to separate the sludge and the clean liquid.

Flotation tanks used for flocculation flotation using the principle of flocculation and flotation can be classified into two types. One is a rapid mixing paper which rapidly agitates flocculant, air and suspension, floc forming paper which performs high speed agitation for growth of flocculation flotation, and flocculation flotation and floating flocculation flotation and cleansing liquid. It is horizontal flow injuries.

The other is the so-called contact, which contains flocculation flotation already present inside the flotation vessel, newly introduced suspensions, flocculants and air in the same flotation vessel and is mainly stirred by the mechanism and which promotes growth of flocculation which is more likely to float than electrons. It is premature.

In comparison, the former requires 4 to 8 hours of injuries due to the relatively small particle size of the flocculating flotation and the slow settling rate, whereas the latter has a large particle diameter which is more susceptible to flocculation than the former. After a short time of ~ 2 hours, there is a big difference in the capacity of the flotation.

As described above, the horizontal flow flotation tank has a large capacity and the equipment cost and facility site have excessive defects. Therefore, the maintenance of the horizontal flow flotation tank is easier than that of the contact flotation tank. Attempts are being made to reduce costs and reduce equipment costs.

However, this conventional flocculation flotation has the advantage of increasing the flocculation flotation efficiency, there is a problem that a separate means must be taken to remove the foreign matter.

The present invention was created in order to solve the above problems, by putting a flocculant and microbubbles into the livestock manure or sewage water to increase the cohesive efficiency to facilitate the flocculation and flotation, and to remove foreign substances at the same time and easily discharge the injured sludge. The purpose is to provide a microbubble floating solid-liquid separation device.

The micro-bubble floating solid-liquid separation device of the present invention for achieving the above object is a multi-pack cyclone for separating the sedimentable contaminants in the treated water by turning the treated water including livestock manure or sewage; An agglomeration reaction unit which adds aggregating agent and air to the treated water discharged from the cyclone and is stirred at the same time; And a solid-liquid separator for solid-liquid separation of the water to be treated through the flocculation reaction part into a supernatant and sludge.

The agglomeration reaction unit is a reaction tank into which the treated water discharged from the multi-cyclone through the lower wastewater inlet pipe installed in the upper, a support frame is installed to be supported on the upper portion of the reaction tank, and installed inside the reaction tank is hollow Is formed in the stirring chamber, the lower portion of the stirring chamber and the flow port formed so that a portion of the treated water introduced into the reaction tank can be distributed into the stirring chamber, and rotatably supported on the support frame and extending to the stirring chamber An impeller coupled to a rotating shaft and a lower portion of the rotating shaft and disposed inside the stirring chamber and discharging upwardly the object to be treated introduced into the stirring chamber, and an upper portion of the stirring chamber on an area between the support frame and the impeller. Obstruction plate which induces turning downwards by interfering with the number of treatment objects discharged through And, one end is connected to the coagulant supply unit and the other end penetrates the support frame and extends into the stirring chamber and the coagulant supply pipe is supplied, one end is connected to the air supply and the other end is passed through the support frame and the stirring And an air inlet pipe extending to the inside of the chamber and provided with an outlet facing the outlet of the flocculant supply pipe.

The solid-liquid separation unit includes a first separation unit which is connected to the agglomeration reaction unit and an outlet pipe, in which the agglomerated reaction target water is stirred, and a second separation unit which solid-liquidly separates the treated water discharged from the first separation unit. The first separation unit includes a first separation tank, a mixing chamber installed inside the first separation tank and connected to the outlet pipe to introduce the water to be treated from the agglomeration reaction unit, and the mixing chamber includes the first separation tank. A support for supporting spaced apart from the bottom, a stirring means installed inside the mixing chamber to stir the water to be treated, the flocculant and the air, and a diffusion chamber installed inside the mixing chamber so as to be positioned below the stirring means; Is formed in the lower portion of the diffusion chamber extends to be spaced apart from the bottom of the first separation tank penetrating the lower portion of the mixing chamber to distribute the water to be treated It is characterized by including a distribution pipe.

The second separation unit may be installed at a rear end of the first separation tank so that the second separation tank into which the object water flows from the first separation tank through the upper part, and a part of the object of the second separation tank may be sucked into the mixing chamber. A suction pipe installed inside the second separation tank so as to be connected to the mixing chamber and provided with a plurality of suction ports, and a supernatant discharge means installed at one side of the second separation tank to discharge the supernatant while adjusting the level of the second separation tank; Characterized in that.

The agglomeration reaction unit is provided with at least two reaction tanks are arranged continuously in multiple stages, the connection pipe connected in a tangential direction with the reaction tanks interconnecting the upper portion of the adjacent reaction tanks to form a swirl flow to the treated object flowing into each reactor It characterized in that it further comprises.

As described above, according to the present invention, it is possible to greatly improve the efficiency of sludge flocculation of livestock manure or sewage by mixing and uniformly generating microbubbles simultaneously with the addition of flocculant in the flocculation reaction part.

In addition, the multi-pack cyclone is arranged at the front end and the agglomeration reaction part and the solid-liquid separation part for the agglomeration reaction at the rear end to facilitate the cohesion and flotation, and also have a structure that can remove the foreign matter early and easily discharge the sludge.

1 is a block diagram schematically showing the configuration of a solid-liquid separation device according to an embodiment of the present invention,
2 is a cross-sectional view showing the solid-liquid separator of FIG.
3 is a cross-sectional view showing an extract of the first reactor applied to FIG.
4 is a partial cutaway perspective view showing an extract of the first reactor applied to FIG.
5 is a partial cutaway perspective view showing an extract of the second separation tank applied to FIG.
Figure 6 is a plan view of the aggregation reaction unit applied to Figure 2,
7 to 11 is a block diagram schematically showing the configuration of a solid-liquid separation device according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the micro-bubble floating solid-liquid separation device by low vacuum mixing according to a preferred embodiment of the present invention.

1 to 5, the solid-liquid separation device of the present invention is a solid-liquid separation by increasing the flocculation efficiency by adding a coagulant and a fine bubble to the treated water at the same time. Here, the water to be treated includes livestock manure or sewage.

The solid-liquid separator of the present invention includes a multi-pack cyclone (1), an agglomeration reaction unit (20), and a solid-liquid separator (70). Cyclone (1) is to separate the large gravity of the contaminants among the foreign matter contained in the sewage water by turning the incoming water to be treated, and includes a casing (3) and a collecting container (10) formed in the lower portion of the casing.

The casing 3 has a cylindrical structure with the top closed and the bottom open. An inlet 5 through which the water to be treated is introduced is formed at the upper side of the casing 3, and one end of the water inlet pipe 7 to be treated is connected to the inlet 5. The other end of the treated water inlet pipe 7 is connected to a treated water supply source (not shown) that supplies the treated water. Examples of sources of treatment are livestock manure or sewage generating facilities or storage tanks in which livestock manure or sewage is stored. The cyclone 1 is formed at a lower position than the source of the water to be treated, or the pump is treated by the pump so that the object water flowing into the casing 3 through the treated water inlet pipe 7 has a constant speed. Can be pumped into.

The treatment object inlet pipe 7 is tangentially connected to the side of the casing 3 so that the treatment object introduced through the treatment object inflow pipe 7 can easily form a swirl flow on the inner circumferential surface of the casing 3. . Although not shown, a plurality of feathers inclined on the inner circumferential surface of the casing 3 are installed at regular intervals to induce vortices in the water to be treated.

The treated water flowing into the casing 3 forms a spiral swirl flow inside the casing 3, and solid foreign matters having a relatively large particle size, such as coarse contaminants such as earth and sand, heavy metals, and various foreign matters in the treated water, are settled. . At this time, the complexes having various kinds, weights, and sizes included in the water to be treated are settled by various mechanisms such as centrifugal force, cohesion and binding between each other, turbulence dispersion and collision, and are introduced into the collecting container 10.

The lower portion of the collecting container 10 is formed in a conical shape that gradually decreases in diameter as it is lowered to facilitate the external discharge of the contaminants. The lower end of the collecting container 10 is connected to the discharge of the contaminants 13 to discharge the contaminants to the outside. The inside of the casing 3 is provided with a treatment object water discharge pipe 9 through which the treatment object water from which the contaminants have been removed can be discharged. The water discharge pipe 9 to be treated extends through the upper surface of the casing 3 to the agglomeration reaction part 20.

The agglomeration reaction unit 20 agglomerates solids by adding a coagulant to the treated water discharged from the multi-pack cyclone 1 and at the same time, fine bubbles are mixed with the coagulant to raise flocculated flocs.

The aggregation reaction unit 20 may include one reactor or two or more reactors. Preferably, three reactors are arranged in multiple stages in a row. This is because an alkali agent, a coagulant aid, a coagulant, etc. can be appropriately applied according to the properties of the water to be treated to increase the coagulation efficiency. In the illustrated example, an agglomeration reaction unit in which a reactor is arranged in three stages is illustrated. For convenience of explanation, the first, second, and third reactors 21, 61, and 65 are sequentially called from the front end.

Each of the first, second, and third reactors 21, 61, 65 is formed in a cylindrical structure having a space of a predetermined size therein. On the open upper portion of each of the reaction tanks 21, 61, 65, a support frame 23 supporting the rotating shaft 40 to be described later is installed. The support frame 23 has a role as a cover together. Reactors 21, 61, 65 are connected to connecting tubes 67, 69, respectively. For convenience of description, the first connecting pipe 67 connects the first and second reactors 21 and 61 and the second connecting pipe 69 connects the second and third reactors 61 and 65. Separate. Through the first and second connecting pipes 67 and 69, the number of treatment targets is sequentially from the first reactor 21 to the second reactor 61, and from the second reactor 61 to the third reactor 65. Inflow. Preferably, the first and second connecting pipes 67 and 69 are formed of first, second and third reaction tanks so that the treated water flowing into the second and third reactors 61 and 65 forms a swirl flow. 21, 61, 65 are connected tangentially. The outlet 22 formed in the upper portion of the first reactor 21 and the inlet 62 formed in the upper portion of the second reactor 61 are connected by the first connecting pipe 67. And an outlet (not shown) formed in the upper portion of the second reactor 61 and the inlet (not shown) formed in the upper portion of the third reactor (65) is connected to the second connecting pipe (69).

The first reaction tank 21 is connected to the treatment object water discharge pipe 9 of the multi-pack cyclone and the treated water passing through the multi-pack cyclone 1 is introduced into the first reactor 21. The treated water discharge pipe 9 is connected to the upper portion of the first reactor 21. Unlike this, the treatment object discharge pipe 9 may be tangentially connected to the upper side surface of the first reactor 21 to form swirl flow in the treatment object introduced into the first reactor 21.

The stirring chamber 30 is installed inside the first reactor 21. The stirring chamber 30 has a hollow inside and a flow opening 37 through which water to be treated is introduced. In addition, a plurality of discharge holes 31 are formed on the upper surface of the stirring chamber 30 to discharge the water to be treated to the outside of the stirring chamber 30.

Some of the treated water introduced into the first reaction tank 21 through the treated water discharge pipe 9 is introduced into the stirring chamber 30 through the distribution port 37. The water to be treated introduced into the stirring chamber 30 is stirred by the impeller 47. To this end, the rotating shaft 40 penetrates through the support frame 23 installed on the upper portion of the first reactor 21 and extends to the upper portion of the stirring chamber 30. The rotating shaft 40 is supported to be rotatable by the bearing 45 installed in the support frame 23. The drive motor 43 is installed outside the first reactor 21 is connected to the rotary shaft 40. The rotating shaft 40 extending to the stirring chamber 30 penetrates through the center of the upper surface of the stirring chamber 30. Impeller 47 coupled to the lower portion of the rotary shaft 40 is composed of a plurality of blades (49) that extend in the direction in which the outer diameter is extended to proceed downward about the rotary shaft (40).

In order to supply the coagulant into the stirring chamber 30, one end is connected to the coagulant supply unit, and the other end passes through the support frame 23 to extend into the stirring chamber 30, and the coagulant supply pipe 50 is supplied with the coagulant. This is installed. The coagulant supply unit includes a coagulant storage tank 51 and a metering pump 53 installed in the coagulant supply pipe 50 connected to the coagulant storage tank 51 to quantitatively pump the coagulant.

In order to generate the micro bubbles in the stirring chamber 30, one end is connected to the air supplier 59, and the other end thereof passes through the support frame 23 and extends to the inside of the stirring chamber 30. ). The air supplier 59 has a conventional structure capable of generating micro bubbles.

While the water to be treated is stirred by the impeller in the stirring chamber, air and a flocculant are introduced into the stirring chamber to mix uniformly. Microbubbles improve flocculation efficiency and float floc-type sludge to the surface.

The outlet of the coagulant supply pipe 50 and the air inlet pipe 57 is formed to face for effective stirring. To this end, the lower part of the coagulant supply pipe 50 and the air inlet pipe 57 is formed by bending in a direction facing each other around the impeller 47. Therefore, the flocculant and the air flow into the impeller 47 from the left and right sides of the stirring chamber 30 and from the lower side of the stirring chamber 30. That is, the water to be treated, the flocculant, and the air come into contact with each other in the three-side direction as in the T-shape. When the impeller 47 rotates according to the driving of the driving motor 43, low vacuum is formed inside the stirring chamber 30 where the turning force of the impeller 47 is generated. Due to such low vacuum, the water to be treated is sucked through the distribution port 37. As described above, according to the present invention, the treatment target water, the flocculant, and the air are uniformly mixed by the low vacuum mixing in the stirring chamber and discharged upward through the discharge hole 31.

The baffle plate 25 is installed on the area between the support frame 23 and the impeller 47. The obstruction plate 23 functions to induce a downward turn by interfering with the water to be discharged through the discharge hole 31 of the stirring chamber 30. The object water turned downward is introduced again into the stirring chamber 30 through the distribution port 37, stirred with the flocculant, and discharged upward. In this way, the agglomeration efficiency can be increased by circulating the water to be treated up and down to increase the number of times of stirring. In addition, an ultrasonic generator 26 capable of applying ultrasonic waves to the object to be rotated on the obstruction plate may be installed.

The floc type sludge formed by the first agglomeration reaction in the first reactor 21 is floated by the microbubbles and flows into the second reactor 61 through the first connecting pipe 67 together with the water to be treated. The water to be treated by the second agglomeration in the reactor 61 is introduced into the third reactor 65 through the second connecting pipe 69 together with the rising sludge. Since the internal structures of the second reactor 61 and the third reactor 65 are the same as those of the first reactor 21, detailed descriptions thereof will be omitted.

The aggregation reaction unit 20 having the above-described structure may be different from the flocculant supplied to each of the reaction tanks 21, 61, 65. In addition to the flocculant, an alkali agent, a flocculent aid may be supplied, of course. For example, sodium hydroxide (NaOH) or sodium bicarbonate (NaHCO ₃ ) in the first reactor 21, sulfuric acid (H ₂ SO ₄ ) in the second reactor 61, and aluminum sulfate (Al ₂ ( Inorganic coagulants such as SO ₄ ) ₃ ) can be supplied.

The water to be treated by the coagulation reaction unit 20 through the coagulation reaction unit 20 is introduced into the solid-liquid separator 70 through an outlet pipe 68 installed at the upper portion of the third reaction tank 65. The solid-liquid separator 70 separates the treated water that has undergone the coagulation reaction unit 20 into a supernatant and sludge.

The solid-liquid separator 70 separates the first separation unit 80 for stirring the agglomerated reaction target water and the second separation for solid-liquid separation while the treatment target water discharged through the upper portion of the first separation unit 80 remains. The unit 120 is provided.

The first separation tank 81 constituting the first separation unit 80 has a cylindrical shape having a predetermined size space therein. The support frame 83 is installed at an open upper portion of the first separation tank 81. The mixing chamber 90 is provided inside the first separation tank 81. The mixing chamber 90 is formed in a cylindrical shape with an open top. A conical portion 91 is formed in the lower portion of the mixing chamber 90 in which the space gradually decreases as it proceeds downward. And the lower part of the cone portion 91 is formed with a distribution port 92 through which the water to be treated. The outflow pipe 68 extends into the mixing chamber 90 so that the water to be treated flows from the aggregation reaction unit 20. The mixing chamber 90 is supported to be spaced apart from the bottom of the first separation tank 81 by the support 93. The support 93 is radially formed in the upper and lower portions of the mixing chamber 90, respectively.

Inside the mixing chamber 90, stirring means for stirring the water to be treated and the flocculant is provided. Stirring means 105, a rotating shaft 97 that is rotated by the drive motor 99, the impeller 106 connected to the rotating shaft 97 and installed inside the stirring chamber 105, the coagulant supply pipe 110 as a stirring means ), An air inlet pipe 115, and a baffle plate 108. Such a configuration includes a stirring chamber 30 installed in the first reaction tank 21 of the agglomeration reaction unit 20, a rotation shaft 40, an impeller 47, a coagulant supply pipe 50, and an air inlet pipe 57. ) And the baffle plate 25 have the same configuration, and thus detailed description thereof will be omitted.

In addition, a conical diffusion chamber 100 is installed inside the mixing chamber 90. The diffusion chamber 100 is located below the stirring chamber 105. In addition, a distribution pipe 101 is formed below the diffusion chamber 100. The distribution pipe 101 extends to be spaced apart from the bottom of the first separation tank 81 by passing through the distribution port 92 of the mixing chamber 90.

The treatment object water discharged from the flocculation reaction unit 20 by the first separation unit 80 having the above-described configuration flows into the mixing chamber 90, is stirred with the flocculant in the stirring chamber 105, and at the same time, microbubbles are introduced. do. The object to be treated is discharged upward through the discharge hole 109 of the stirring chamber 105 and collides with the inclined plate 108 to pivot downward. The treatment object water turning downward is introduced through the distribution pipe 101 and diffused into the diffusion chamber 100 and mixed with the treatment object water discharged from the flocculation reaction unit 20 again to flow into the stirring chamber 105 and uniformly. Are mixed.

The water to be treated having passed through the first separation tank 81 is introduced into the second separation unit 120 through the outlet pipe 107 installed on the upper portion of the first separation tank 81.

The second separation unit 120 includes a second separation tank 121, a suction tube 140, and a supernatant discharge means.

In addition, a suction pipe 140 is installed inside the second separation tank 121. The suction pipe 140 is spaced a predetermined distance from the bottom of the second separation tank 121. The suction pipe 140 is provided with a plurality of suction ports 145. The suction pipe 140 is connected to the mixing chamber 90 of the first separation tank 81. Due to the low vacuum generated in the stirring chamber 105 by the rotation of the impeller 106, a part of the water to be treated in the second separation tank 121 is re-introduced into the mixing chamber 90 through the suction pipe 140.

The supernatant discharge means is composed of a supernatant suction pipe 150 and a pump 155 for transmitting suction to the supernatant suction pipe 150. Although not shown, the supernatant suction pipe 150 may be configured to move up and down by lifting means to adjust the suction height. Therefore, the level of the second separation tank 121 may be adjusted according to the height of the supernatant suction pipe 150. The supernatant suction pipe 150 is disposed in the retention space 129 formed by the partition wall 127 installed in the second separation tank 121. The partition 127 is spaced apart from the bottom of the second separation tank 120.

On the other hand, a scum skimmer 130 is installed on the upper portion of the second separation tank 121 to remove the suspended matter including the floating sludge. Scum cummer 130 is a conventional structure that is applied to the water treatment apparatus, a detailed description thereof will be omitted. The suspended matter removed through the scum cummer 130 is discharged to the outside through the float discharge pipe 133. The treated water introduced into the second separation tank 121 stays for a certain time and finally separates the sludge and the supernatant is discharged to the outside.

The drain pipe 135 for drainage is connected to the bottom of the first separation tank and the second separation tank.

Another embodiment of the present invention is shown in FIG. In the embodiment of FIG. 7, the aggregation reaction unit 200 includes two reaction tanks, namely, first and second reaction tanks 21 and 61. In FIG. 8, the aggregation reaction unit 210 includes one reaction tank 21. In addition, in the embodiment of Figure 9, the solid-liquid separator is composed of a multi-pack cyclone (1) and the solid-liquid separator (70).

Components not described above in the embodiments illustrated in FIGS. 7 to 9 are the same as the embodiments illustrated in FIG. 1, and thus detailed descriptions thereof will be omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation.

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

1: multi-pack cyclone 20: agglomeration reaction part
21: first reactor 25: baffle plate
30: stirring chamber 40: rotating shaft
43: drive motor 47: impeller
50: flocculant supply pipe 57: air inlet pipe
70: solid-liquid separator 80: first separation unit
90: mixing chamber 120: second separation unit

Claims (5)

A multi-pack cyclone for separating sedimentable contaminants in the treated water by turning the treated water including livestock manure or sewage water; An agglomeration reaction unit in which a flocculant and air are simultaneously introduced into the treated water discharged from the multi-pack cyclone and stirred; And a solid-liquid separator for solid-liquid separation of the water to be treated that has undergone the flocculation reaction into a supernatant and sludge.
The solid-liquid separator comprises a first separation unit which is connected to the flocculation reaction part and an outlet pipe and stirs the agglomerated reaction target water, and a second separation unit which is solid-liquid separated while the treatment target water discharged from the first separation unit stays. Equipped,
The first separation unit is formed in a cylindrical shape having a first separation tank and a conical portion provided in the lower portion of the first separation tank, the upper portion of which is opened and the space gradually decreases as it proceeds downward, and the outlet pipe is connected to the aggregation. A mixing chamber into which the treatment object water flows from the reaction unit, a support for supporting the mixing chamber so as to be spaced apart from the bottom of the first separation tank, and stirring means installed in the mixing chamber to stir the treatment water, the flocculant, and the air; And a conical diffusion chamber installed inside the mixing chamber so as to be positioned below the stirring means, and formed below the diffusion chamber and spaced apart from the bottom of the first separation tank by passing through a distribution port provided in the lower portion of the cone portion. Have a distribution pipe that extends and distributes the water to be treated;
The second separation unit is installed at a rear end of the first separation tank, and a second separation tank into which the object water flows from the first separation tank through the upper part, and a part of the object water of the second separation tank is sucked into the mixing chamber. A suction pipe installed inside the second separation tank so as to be connected to the mixing chamber and provided with a plurality of suction ports, a partition wall installed at an inner rear side of the second separation tank to form a retention space, and a supernatant liquid installed in the residence space And a supernatant discharge means for adjusting the water level of the second separation tank while discharging the supernatant through the suction pipe, and a scum skimmer installed in the second separation tank to remove floating matters floating in the second separation tank. Floating solid-liquid separator for microbubbles by low vacuum mixing. The reactor of claim 1, wherein the agglomeration reaction part comprises a reaction tank into which the object water discharged from the multi-pack cyclone is introduced through a treatment water inlet pipe installed at an upper portion thereof, a support frame installed to be supported on the upper portion of the reaction tank, and inside the reaction tank. A stirring chamber installed in the inside of the stirring chamber and a hollow portion formed at a lower portion of the stirring chamber and configured to distribute a portion of the water to be treated introduced into the reactor into the stirring chamber, and being rotatably supported by the support frame. And an impeller coupled to the rotary shaft extending to the stirring chamber, the impeller being coupled to the lower portion of the rotary shaft and disposed inside the stirring chamber to discharge the treated water flowing into the stirring chamber upwardly, and between the support frame and the impeller. Down the line by interfering with the water to be discharged through the upper part of the stirring chamber A baffle plate for inducing a, one end connected to the coagulant supply part and the other end extending through the support frame to the inside of the stirring chamber, and the coagulant supply pipe to which the coagulant is supplied, and one end connected to the air supply and the other end to the support frame. Floating solid-liquid separation device by low vacuum mixing characterized in that it comprises an air inlet pipe extending through the stirring chamber and the outlet facing the outlet of the flocculant supply pipe. delete delete According to claim 2, wherein the agglomeration reaction unit is provided with at least two or more of the reaction tank is continuously arranged in multiple stages,
Floating solid solution separation by low vacuum mixing, characterized in that it further comprises a connecting pipe connected to the upper portion of the adjacent reaction tanks in a tangential direction with the reaction tank to form a swirl flow to the treated object flowing into the respective reaction tanks Device.

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