KR102054499B1 - Flocculation equipment for water treatment - Google Patents

Abstract

In the present invention, the mixed solution of raw water and flocculant is introduced into the cylindrical reactor in the tangential direction, and the stirring and floc are formed by the kinetic energy at the inflow, so that the stirring device can be omitted, and the floc in the sequential flow of the mixed solution This formation provides an agglomeration reaction apparatus for water treatment that can prevent the ungrown floc from being discharged to the next process through a shortened path.

Description

Coagulation Reactor for Water Treatment {FLOCCULATION EQUIPMENT FOR WATER TREATMENT}

Embodiment of the present invention relates to a flocculation reaction apparatus used in the flocculation process using flocculation chemicals for removing suspended solids in raw water.

One of the most basic processes of water purification technology is to remove suspended solids dispersed in water.

The most commonly adopted method for the efficient removal of suspended solids in water is to inject chemicals into the water, causing the suspended solids to become entangled with each other, which speeds up the settling or injury. Two processes, namely, coagulation and flocculation, in which chemicals and suspended solids are entangled with each other, are carried out at a rapid rate. Remove suspended solids by using flotation separation.

In the mixing process, a method of mixing the medicine and water evenly by a turbulent flow generated inside the tube by performing a relatively strong stirring within a few minutes within a mixing reactor equipped with a stirring device or passing the inside of a long tube at a high speed is adopted. In the coagulation process, it is common practice to perform relatively weak agitation in a relatively large coagulation reactor equipped with an agitation device so that the chemicals and suspended solids are entangled as large as possible, causing collisions with each other at an appropriate strength. . Aggregates of suspended solids by drugs are usually called flocs.

Conventional flocculation process requires time to cause the flocculation reaction. When performing the flocculation reaction in a continuous process in one reactor, the newly introduced mixed water is randomly mixed into the next process. As this is not done, the flocculation is not sufficiently coagulated and the floc is mixed with ungrown mixed water at a constant rate, and these ungrown flocs serve as one cause of lowering the treatment efficiency in the precipitation or flotation process. . For this reason, in order to make up for the deterioration of treatment efficiency, the reaction tank is made large so that it is necessary to increase the residence time in the tank or increase the capacity of the sedimentation or flotation separation tank, which is the next process, which is a problem from an economic point of view.

On the other hand, since the agitation apparatus is attached to a conventional coagulation reaction tank, there is a disadvantage of causing an increase in manufacturing cost.

As a countermeasure for the above problems, in Korean Patent Publication Nos. 10-1232734 and 10-1232884, agglomeration occurs while agglomeration target liquid passes through a channel by forming a channel around a precipitation device and installing a baffle inside. Disclosed is a method to make it. However, the flow of water occurring in the space where the channel and the baffle are combined cannot avoid the difference between the stagnant region of water generated in the front and rear of the baffle and the flow velocity occurring in the lower and upper portions of the channel, so Despite the disturbance effect with the decrease of the real residence time, the shortest path on the channel is generated, thereby preventing the occurrence of probable ungrown flocs.

Republic of Korea Patent Publication No. 10-1232734 (2013.02.13.) Republic of Korea Patent Publication No. 10-1232884 (2013.02.13.)

Embodiment of the present invention is to provide a flocculation reaction device for water treatment more advantageous in terms of improving the efficiency and economic efficiency of the flocculation reaction. That is, as the mixed solution of raw water and flocculant does not have sufficient floc growth time, it is intended to solve the problem of being discharged to the next process in an ungrown floc state and the economic burden due to the application of the stirring device.

The problem to be solved is not limited thereto, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to an embodiment of the present invention, the cylindrical reaction tank is passed through the circular discharge hole in the center of the bottom; At least one mixed solution supply pipe connected tangentially to the circumference of the reactor; A flocculation reaction apparatus for water treatment may be provided, including a flocculation liquid discharge pipe connected downward to the discharge hole of the reaction tank.

The agglomeration liquid discharge pipe may be provided with a level control means for maintaining the internal space of the reactor at a constant level through controlling the discharge of the agglomeration liquid.

The water level adjusting means may include an inverted U-shaped pipe connected to the distal end of the agglomeration liquid discharge pipe and erected at a predetermined height.

The mixed liquid supply pipe may be connected to a range of 10% of the total height of the inner space at the bottom of the inner space of the reactor.

Means for solving the problems will become more specific and clear through the embodiments, drawings, and the like described below. In addition, in the following, various solutions other than the above-mentioned solutions may be further presented.

According to an embodiment of the present invention, since the mixed liquid supply pipe and the condensed liquid discharge pipe are connected to a simple cylindrical reaction tank, not only is it easy to manufacture and economical, but also the power at the time of inflow of the mixed liquid of raw water and the flocculant into the reaction tank ( Since flocs are formed while flowing along a predetermined path in the inner space of the reactor with kinetic energy), the floc grows with uniform agglomeration so that ungrown flocs do not occur, thereby maximizing the flocculation reaction efficiency in the reactor. The effectiveness of the sedimentation or flotation process for subsequent floc separation and removal can be enhanced.

1 is a perspective view showing the configuration of a flocculation reaction apparatus for water treatment according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along the line AA of FIG. 1.
3 is a perspective view showing the operation of the flocculation reactor for water treatment according to the first embodiment of the present invention.
Figure 4 is a perspective view showing the configuration of a flocculation reaction device for water treatment according to a second embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. For reference, in the drawings referred to describe the embodiments of the present invention, the size of the component, the thickness of the line, etc. may be somewhat exaggerated for convenience of understanding. In addition, the terms used to describe the embodiments of the present invention are mainly defined in consideration of functions in the present invention, and may vary according to intentions, customs, and the like of users and operators. Therefore, the terms should be interpreted based on the contents throughout the present specification.

The configuration, operation, and the like of the flocculation reaction apparatus for water treatment according to the first embodiment of the present invention are shown in FIGS.

1 to 3, the flocculation reaction apparatus for water treatment according to the first embodiment of the present invention, the reaction tank 10, the raw water (including the floating material) and the flocculating chemicals are arranged in the vertical direction A mixed liquid supply pipe 14 for supplying the mixed liquid to the inner space (agglomeration reaction space) of the reaction tank 10, and an agglomerated liquid discharge pipe 15 through which the agglomerated liquid having completed the agglomeration reaction in the inner space of the reaction tank 10 is discharged. .

In addition, the flocculation reaction apparatus for water treatment according to the first embodiment of the present invention further includes a level control means 27 for maintaining the height of the water surface 25 in the reaction tank 10 at a predetermined level.

The reaction vessel 10 includes a cylindrical wall 11 and a circular bottom plate 12 that blocks an open lower portion of the wall 11 and is defined by the wall 11 and the bottom plate 12. The space is configured to be internal space.

As shown in FIG. 1, the bottom plate 12 constituting the bottom of the inner space in the reaction tank 10 is provided with a discharge hole penetrating the bottom plate 12 in the vertical direction, and the coagulation liquid after the coagulation reaction is discharged. It is discharged to the outside from the internal space of the reaction tank 10 through the hole. As shown in FIG. 2, the discharge hole is disposed at the center of the bottom of the reaction vessel 10 and is formed in a circular shape.

The mixed liquid supply pipe 14 is provided in singular or plural. As shown in Fig. 1 and 2, the mixed liquid supply pipe 14 is a tangential to the wall 11 constituting the circumference of the inner space in the reaction tank 10 so that the pipe communicates with the inner space of the reaction tank 10. Direction is connected. According to this, the mixed liquid from the mixed liquid supply pipe 14 flows into the inner space of the reaction tank 10, and the mixed liquid thus provided forms a swirl flow in the inner space of the reaction tank 10.

The agglomeration liquid discharge pipe 15 is disposed in the vertical direction. The coagulant discharge pipe 15 is connected to the upper end of the discharge hole of the reaction tank (10).

The operation of the flocculation reaction apparatus for water treatment according to the first embodiment of the present invention is as follows.

When the mixed liquid of the raw water and the flocculant is supplied to the inner space of the reaction tank 10 through the pipe of the mixed liquid supply pipe 14, the mixed liquid introduced into the inner space of the reaction tank 10 is the mixed liquid supply pipe 14 of the reaction tank 10. Swirl flow is formed in the inner space of the reactor 10 by the configuration tangentially connected to the circumference and the power (that is, the kinetic energy) at the inflow.

Then, when the mixed liquid is continuously supplied to the internal space of the reaction tank 10 through the mixed liquid supply pipe 14, the mixed liquid supplied at this time has a relatively high speed (relatively large velocity energy), and is represented in FIG. 3. As described above, a turning upward flow 21 is formed in the inner space of the reaction tank 10 while turning along the inner wall of the inner space.

In addition, if the mixed liquid is continuously supplied to the internal space of the reaction tank 10, the mixed liquid fills the internal space of the reaction tank 10 with a predetermined level to form a turning down stream 23 that descends while turning in the central region of the internal space. do. At this time, the turning upflow 21 and the turning down flow 23 coexist in the internal space of the reaction tank 10 as shown in FIG.

Here, the turning upward flow 21 has a velocity gradient toward the center from the point of contact with the inner wall of the inner space in the reaction tank 10 to form a constant turbulence, and at the same time, the turning downward flow The discontinuity is formed at the boundary with the flow 23 and the speed is changed to receive energy to form another turbulence.

In this process, the suspended solids in the mixed solution proceeds to agglomeration, the floc continues to grow to a certain size, and the agglomerated liquid is discharged to the agglomerated liquid discharge pipe 15 through the discharge hole. That is, continuously changing the flow down to the turning 23, the floc continues to grow under the condition of the weakened shear force to move to the next process.

The reason why the mixed liquid supplied to the reaction tank 10 forms two paths, the swinging upward flow 21 passing through the peripheral region of the inner space and the swirling downward flow 23 passing through the central region of the inner space, are as follows.

When the mixed liquid flowing into the inner space of the reactor 10 starts turning at a relatively high linear speed at the inlet point, the center side of the turning is placed in a low pressure state due to the centrifugal force. As the mixed liquid flows up, the turning speed decreases due to friction. As a result, the pressure of the mixed liquid inlet point is highest, the pressure at the center of the mixed liquid turning point is lowest, and as the distance from the mixed liquid inlet point decreases, the pressure difference between the peripheral and central regions decreases due to the decrease of the revolution speed. The flow of the turning upflow 21 and the turning downflow 23 is formed according to the reason which flows from this high place to the low place.

In order for the mixed liquid supplied to the reaction tank 10 to sufficiently pass through the paths of the turning upward flow 21 and the turning downward flow 23 sequentially, the connection position of the mixed liquid supply pipe 14 is relative to the circumference of the reaction tank 11. It is advantageous to be on the lower side. In general, it is preferable to connect the mixed liquid supply pipe 14 to a range of 10% of the total height of the inner space at the bottom of the inner space.

The discharge hole to which the agglomeration liquid discharge pipe 15 is connected is preferably exactly positioned at the center of the bottom of the inner space in order to maintain smooth swirl flow in the reaction tank 11.

The water level adjusting means 27 is connected to the end (lower end) of the flocculation liquid discharge pipe 15 and may be configured as an inverted U-shaped pipe erected at a predetermined height. Alternatively, the water level control means 27, the water level sensor for detecting the water level of the reaction tank 10 and the flow control valve mounted on the flocculation discharge pipe 15, the flow control valve is opened and closed according to the detection result of the water level sensor And may be configured to maintain a constant level.

4 shows an agglomeration reaction apparatus for water treatment according to a second embodiment of the present invention. As shown in FIG. 4, in the flocculation reaction apparatus for water treatment according to the second embodiment of the present invention, when compared with the first embodiment of the present invention, the bottom plate 13 of the reaction vessel 10 has a conical shape. Only the points formed as are different.

That is, the flocculation reaction apparatus for water treatment according to the second embodiment of the present invention is formed such that the bottom plate 13 has an inner circumference which is reduced toward the lower side, so that the floc generated in the inner space of the reactor 11 is relatively If it is heavy, it can prevent the accumulation of sediment on the bottom of the inner space.

On the other hand, although not shown, the flocculation reaction apparatus for water treatment according to the first or second embodiment of the present invention, in the reaction tank 10 is generated in the inner space on at least one of the bottom and the inner wall of the inner space. Unevenness may be formed or protrusions may be provided to adjust the intensity of the turbulence.

The present invention has been described above, but the present invention is not limited to the disclosed embodiments and the accompanying drawings, and may be variously modified by those skilled in the art without departing from the technical spirit of the present invention. In addition, the technical idea described in the embodiments of the present invention may be implemented independently, or two or more may be implemented in combination with each other.

10: reactor
11: wall of the reactor
12, 13: bottom plate of the reactor
14: mixed liquid supply pipe
15: aggregation liquid discharge pipe
21: slewing upward flow
23: turning down stream
25: water surface
27: level control means

Claims (4)

A cylindrical reactor having a circular discharge hole penetrated at the center of the bottom;
At least one mixed solution supply pipe connected tangentially to the circumference of the reactor;
And a coagulation liquid discharge pipe connected downward to the discharge hole of the reaction tank.
The agglomeration liquid discharge pipe is provided with a level control means for maintaining the internal space of the reactor at a constant level through controlling the discharge of the agglomeration liquid,
The upper end of the flocculation discharge pipe is connected to the lower portion of the discharge hole of the reaction tank, the lower end of the flocculation reaction device for water treatment is connected to the water level adjusting means. delete The method according to claim 1,
The water level adjusting means,
Including an inverted U-shaped tube connected to the distal end of the condensate discharge pipe and erected to a certain height
Aggregation reactor for water treatment. The method according to claim 1 or 3,
The mixed liquid supply pipe is connected to the 10% range of the total height of the inner space at the bottom of the inner space of the reactor,
Aggregation reactor for water treatment.

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