KR102539046B1 - Apparatus for dissolving air - Google Patents

Abstract

The present invention can improve air dissolution efficiency by optimizing factors that affect air dissolution efficiency, such as residence time of circulating water and air, contact efficiency between circulating water and air, and refinement of air, while minimizing device complexity. It relates to an air dissolving device, and the air dissolving device according to the present invention includes a dissolving tank providing a space in which the air dissolving process proceeds; Dissolving tank separators spaced apart and disposed in the vertical direction in the dissolving tank to spatially divide the dissolving tank into a plurality of unit dissolving tanks; A dissolved water supply pipe for upwardly moving the dissolved water in the lower unit dissolving tank to the neighboring upper unit dissolving tank; and a plurality of acid pores provided in the separation plate of the dissolving tank, wherein the lower unit dissolving tank is filled with dissolved water of a certain water level, and an air layer not dissolved in the circulating water is located on the upper part of the water level of the dissolved water, and the lower unit dissolving vessel is It is characterized in that the air of the dissolving tank is supplied to the upper unit dissolving tank through the acid pore of the dissolving tank separator and re-dissolved in the dissolving water filled in the upper unit dissolving tank.

Description

Air dissolving device {Apparatus for dissolving air}

The present invention relates to an air dissolution device, and more particularly, factors affecting air dissolution efficiency, such as residence time of circulating water and air, contact efficiency between circulating water and air, and refinement of air, while minimizing device complexity It relates to an air dissolution device capable of improving air dissolution efficiency by optimizing.

Flotation separation is a method of removing solid particles in water by floating them on the surface of the water. It is a unit operation of separation technology, and at the same time, it is one of the important unit operations applied to sorting, separation of suspended particles, and fractionation of solutes. When bubbles are attached to floating particles, the gas density is remarkably low, so the floating speed of the bubbles and attached particles becomes remarkably fast. In addition, even sedimentary particles can be floated if bubbles can be attached thereto, and this method can generally increase the separation rate and concentration rate in concentration of suspended particles more than the sedimentation method in many cases.

Dissolved air flotation (DAF) is widely used as a method of supplying bubbles to the flotation separation process. The dissolved air flotation method (DAF) is a method in which pressurized air is injected into circulating water at a certain pressure so that the air is dissolved in the circulating water. Air is ejected in the form of microbubbles.

Since the efficiency of the flotation process increases in proportion to the amount of microbubbles supplied, it is necessary to ensure the air dissolution efficiency of the air dissolution device to a certain level or higher. The air dissolution efficiency is determined by the residence time of the circulating water and air in the air dissolving device, the contact efficiency between the circulating water and the air, and the micronization of the air in the circulating water. That is, as the residence time, contact efficiency, and refinement of air increase, the air dissolution efficiency improves.

Korean Patent Registration No. 1838145 secures residence time by extending the pipe in a multi-stage form, improves contact efficiency through a swirling flow device having various mechanical shapes, and rotates-pulse type air injection tip in the air injection pipe. A technique for inducing refinement of air by providing a is proposed. Korean Patent Registration No. 1838145 discloses that air dissolution efficiency can be improved to a certain level by implementing a device that reflects all factors affecting air dissolution efficiency, but a swirling flow device with a complex structure and a rotation-pulse type air injection tip. As this must be provided, device complexity follows.

Korean Patent Publication No. 2012-67394 suggests a technique for inducing contact efficiency and refinement of oxygen by allowing water and oxygen to move repeatedly in the space between the inner tube and the exterior. However, Korean Patent Publication No. 2012-67394 requires that the inner tube and the exterior be configured in a straight line shape over a certain length for contact efficiency and oxygen miniaturization, which may follow limitations in securing installation space.

Korean Patent Registration No. 1838145 (Announced on March 13, 2018) Korean Patent Publication No. 2012-67394 (published on June 26, 2012)

The present invention has been made to solve the above problems, and in a state of minimizing device complexity, the residence time of circulating water and air, contact efficiency between circulating water and air, and air refinement, which affect air dissolution efficiency An object of the present invention is to provide an air dissolving device capable of improving air dissolving efficiency by optimizing factors.

An air dissolving device according to the present invention for achieving the above object includes a dissolving tank providing a space in which the air dissolving process proceeds; Dissolving tank separators spaced apart and disposed in the vertical direction in the dissolving tank to spatially divide the dissolving tank into a plurality of unit dissolving tanks; A dissolved water supply pipe for upwardly moving the dissolved water in the lower unit dissolving tank to the neighboring upper unit dissolving tank; and a plurality of acid pores provided in the separation plate of the dissolving tank, wherein the lower unit dissolving tank is filled with dissolved water of a certain water level, and an air layer not dissolved in the circulating water is located on the upper part of the water level of the dissolved water, and the lower unit dissolving vessel is The air from the dissolving tank is supplied to the upper unit dissolving tank through the acid pore of the dissolving tank separator plate and is re-dissolved in the dissolved water filled in the upper unit dissolving tank.

When the circulating water containing air is supplied to the lowermost unit dissolving tank, the circulating water containing air is filled to a certain level, and the air is dissolved in the circulating water to produce dissolved water. It is supplied to the adjacent upper unit dissolving tank, and the dissolved water in each unit dissolving tank is supplied to the neighboring upper unit dissolving tank through the dissolving water supply pipe. It is supplied to the dissolving water of the upper unit dissolving tank adjacent to it through pores and dissolved therein.

A vent pipe for adjusting the water level is provided on one side of the uppermost unit dissolving tank to control the level of dissolved water in each unit dissolving tank and to discharge non-zone air. The level of the dissolved water rises, and when the water level of the uppermost unit dissolving tank exceeds a certain level, the water level control vent pipe is blocked, leading to the formation of an unexisted air layer and lowering the water level.

A dissolved water discharge pipe for discharging the dissolved water of the uppermost unit dissolving tank to the outside is provided on one side of the uppermost unit dissolving tank, and a pressure holding member composed of an orifice pipe or a bushing is provided in the dissolved water discharging pipe, and the dissolved water is discharged through the pressure holding member. By doing so, it is possible to prevent a loss of pressure inside the melting tank.

The dissolving water supply pipe of the even-stage unit dissolving tank is provided at the first end side of the unit dissolving tank, and the dissolving water supply pipe of the odd-stage unit dissolving tank is provided at the second end side of the unit dissolving tank, and the first and second end sides are provided at both ends of the unit dissolving tank. A dissolved water inlet hole is provided at one side of the dissolved water supply pipe, and a dissolved water outlet hole is provided at the upper end of the dissolved water supply pipe to transfer the dissolved water moved upward along the dissolved water supply pipe to the adjacent upper unit dissolving tank. The male exit hole is arranged in a horizontal direction.

The melting tank has a rectangular parallelepiped shape or a cylindrical shape.

When the dissolving tank has a cylindrical shape, the dissolving tank separator plate has a disk shape, and the dissolving water outlet hole connected to the dissolving water supply pipe is arranged in a horizontal direction on the dissolving tank separator plate and is arranged in an oblique shape toward the circumference of the dissolving tank separator plate It induces swirling flow of dissolved water.

The air melting device according to the present invention has the following effects.

As the circulating water and air sequentially pass through a plurality of unit dissolving tanks arranged in the vertical direction, the residence time of the circulating water and air is secured, and the non-zone air is supplied to the adjacent upper unit dissolving tank through the diffusion hole to be dissolved. Accordingly, refinement of air and re-contact between circulating water and air can be induced, thereby excluding device complexity and improving air dissolution efficiency.

In addition, the residence time of the circulating water and the air can be selectively adjusted through the pressure and flow rate of the circulating water and the air, and the opening and closing operation of the vent pipe.

1 is a block diagram of an air melting device according to an embodiment of the present invention.
2 is a block diagram of an air melting device according to another embodiment of the present invention.
FIG. 3 is a front view of FIG. 1 or 2, and is a reference view for explaining an air melting process in an air melting device.

The present invention proposes a technology related to an air dissolving device capable of improving air dissolving efficiency.

As mentioned above, the air dissolution efficiency improves as the residence time of circulating water and air, the contact efficiency between circulating water and air, and the refinement of air increase. These factors, that is, residence time, In optimizing the contact efficiency and the miniaturization of air, it is necessary to minimize the complexity of the device and eliminate the limitations of the installation space.

The present invention proposes a technology capable of increasing the residence time of circulating water and air, the contact efficiency between circulating water and air, and the miniaturization of air through an optimal design, thereby improving air dissolution efficiency.

Hereinafter, an air melting device according to an embodiment of the present invention will be described in detail with reference to the drawings.

Referring to FIG. 1 , an air dissolving device according to an embodiment of the present invention includes a dissolving tank 10 . The dissolving tank 10 provides a space in which air is dissolved in circulating water.

A circulating water supply pipe 11 is provided at one end of the dissolving tank 10, and a dissolved water discharge pipe 13 is provided at the other end. In addition, an air supply pipe 12 for supplying air to the circulating water supply pipe 11 is provided at one side of the circulating water supply pipe 11 .

The circulating water containing air is supplied to the dissolving tank 10 through the circulating water supply pipe 11, and the circulating water in which the air in the dissolving tank 10 is dissolved, that is, the dissolved water is discharged through the dissolving water discharge pipe 13 to separate by flotation. transferred to Joe Air pressurized at a certain pressure is supplied to the circulating water supply pipe 11 through the air supply pipe 12, and circulating water containing air is supplied to the dissolution bath 10 through the circulating water supply pipe 11.

When the circulating water containing air is supplied to the dissolving tank 10, the circulating water supplied through the circulating water supply pipe 11 and the air supplied through the air supply pipe 12 are both pressurized and supplied at a certain pressure, and the air pressure must be greater than a certain level than the pressure of the circulating water. If the pressure of the air is higher than the pressure of the circulating water by a certain level or more, the air is not dissolved or the air dissolution efficiency is significantly lowered. To this end, the air pressure should be 1.7 to 2 bar greater than the pressure of the circulating water, and in one embodiment, the air pressure may be set to 5 to 7 bar and the pressure of the circulating water to be set to 3 to 5 bar.

A plurality of dissolving bath separators 120 are provided in the dissolving bath 10 . The plurality of dissolving tank separators 120 are spaced apart in the vertical direction, and thus the dissolving tank 10 is spatially divided into a plurality of unit dissolving tanks 110 by the plurality of dissolving tank separators 120 . A process of dissolving air into circulating water in each unit dissolving tank 110 proceeds, and the dissolved water in each unit dissolving tank 110 is supplied to the upper unit dissolving tank 110, which will be described in detail later.

A dissolved water supply pipe 130 is provided in each unit dissolving bath 110 in which a space is formed by the dissolving bath separator 120 . The dissolved water supply pipe 130 is a pipe for supplying the dissolved water to the unit dissolving tank 110 at the top of the unit dissolving tank 110, and has a dissolved water inlet hole 131 and a dissolved water outlet hole 132. . Dissolved water in the unit dissolution tank 110 is introduced through the dissolved water inlet hole 131 and transferred to the unit dissolution tank 110 at the top through the dissolved water supply pipe 130 and the dissolved water outlet hole 132.

The dissolved water supply pipe 130 is provided in a form vertically mounted in the unit dissolved water tank 110, and a plurality of dissolved water inlet holes 131 may be provided along the dissolved water supply pipe 130. In addition, the dissolved water outlet hole 132 provided at the upper end of the dissolved water supply pipe 130 is preferably disposed in the horizontal direction of the unit dissolving tank 110. This is because when the dissolved water outlet hole 132 is disposed in the vertical direction, it is ejected toward the water level surface of the unit dissolving tank 110, and the air dissolved in the circulating water can be dispersed into the unexisted air layer. In addition, when the dissolution tank separator 120 has a disk shape as shown in FIG. 2, the dissolution water outlet hole 132 is horizontally on the dissolution tank separator 120 to induce swirl flow in the unit dissolution tank 110. It is disposed in an oblique shape toward the circumference of the dissolving tank separator 120 with being disposed.

Under this configuration, when the circulating water containing air is supplied to the lowermost unit dissolving tank 110 of the dissolving tank 10 through the circulating water supply pipe 11, the circulating water containing air in the lowermost unit dissolving tank 110 increases by a certain water level. The process of dissolving air into the circulating water by staying together with the filling proceeds, and the circulating water in which the air generated through this process is dissolved, that is, the dissolved water, passes through the dissolved water supply pipe 130 to the unit dissolving tank 110 at the top. It is moved upward (see FIG. 3).

In addition, in disposing the circulating water supply pipe 11, it is preferable that the circulating water supply pipe 11 of the adjacent unit melting tank 110 is disposed at different extreme ends. For example, the circulating water supply pipe 11 of the odd-stage unit dissolving tank 110 is disposed on the first end side of the unit dissolving tank 110, and the circulating water supply pipe 11 of the even-stage unit dissolving tank 110 is the unit dissolving tank ( 110) is preferably disposed on the second end side. The first end side and the second end side mean both ends of the unit dissolution tank 110, and the reason why the circulating water supply pipes 11 of the adjacent unit dissolution tanks 110 are disposed at different extremes is that the circulating water supply pipe 11 ) so that the dissolved water supplied through is convected within the supplied unit dissolving tank 110, the distance that the non-existent air included in the circulating water moves in the horizontal direction within the dissolved water increases, so that the non-existent air and the dissolved water contact This is to increase the time and ultimately increase the air melting efficiency.

Meanwhile, a plurality of acid pores 121 are provided in the dissolution bath separator 120 . The diffuser hole 121 spatially connects adjacent unit dissolving tanks 110 and serves to re-supply the non-zone air of the lower unit dissolving tank 110 to the upper unit dissolving tank 110.

The diffuser hole 121 plays a role of inducing re-contact between circulating water and air as well as inducing refinement of air. In the process of dissolving air in the circulating water in the unit dissolving tank 110 of each stage and supplying the dissolved water of the unit dissolving tank 110 of each stage to the unit dissolving tank 110 at the top, as described above, the unit dissolving tank of each stage Since the dissolved water is filled only to a certain level in the 110, an undissolved air layer not dissolved in the circulating water is located at the upper end of the unit dissolving tank 110.

This non-zone air is supplied to the unit dissolving tank 110 at the top through the diffusion hole 121 (see FIG. 3), and as the dissolved water is filled at a certain level in the unit dissolution tank 110 at the top, the diffusion hole The air supplied to the upper unit dissolving tank 110 through 121 comes into contact with the circulating water again in the upper unit dissolving tank 110 and is dissolved in the circulating water. In addition, since the air is supplied through the diffuser pore 121 of a certain diameter, miniaturization of the air is induced and the air dissolution efficiency is improved. At this time, the unexisted air moves from the unexisted air layer to the upper unit dissolving tank 110 through the diffusion hole 121 due to the difference in pressure and flow rate between the air and the circulating water.

Therefore, the plurality of diffusion holes 121 are arranged at regular intervals across the entire surface of the dissolution tank separator 120, and the diameter of the diffusion holes 121 is determined by the size of the dissolution tank 10, the supply pressure of circulating water, and air. It can be designed considering the supply pressure, circulation water and air flow rate.

In this way, through the configuration of the plurality of diffuser pores 121 provided in the dissolving tank separator 120, miniaturization of air is induced, re-contact between circulating water and air is induced, and horizontal flow of unexisted air is induced. dissolution efficiency can be improved.

Under the configuration as described above, the air melting process of the air melting device according to an embodiment of the present invention proceeds as follows.

When pressurized air is supplied to the circulating water supply pipe 11 through the air supply pipe 12, the circulating water containing air is supplied to the lowermost unit dissolving tank 110 of the air dissolving device through the circulating water supply pipe 11. Accordingly, the circulating water containing air is filled up to a certain level in the lowermost unit dissolving tank 110, and the process of dissolving the air into the circulating water proceeds, and the dissolved water is generated through this process and the generated dissolved water is dissolved. It is moved upward to the unit melting tank 110 at the top through the water supply pipe 130. At this time, in the process in which air is dissolved in the circulating water in the lowermost unit dissolving tank 110 and the generated dissolved water is supplied to the upper unit dissolving tank 110, the dissolved water is filled only to a certain level in the lowermost unit dissolving tank 110. , The air layer is located at the upper end of the lowermost unit melting tank 110.

Located at the upper end of the lowermost unit dissolving tank 110, that is, the air layer located above the level of the dissolved water in the lowermost unit dissolving tank 110 is undissolved air that is not dissolved in the dissolved water in the lowermost unit dissolving tank 110, and the pressure and flow rate difference It is supplied to the upper unit dissolving tank 110 through the diffusion hole 121 provided in the dissolution tank separator 120 by the like, and the upper unit dissolution tank 110 is also filled with dissolved water at a certain level, so that the diffusion hole 121 ) The air supplied through is supplied in the form of fine bubbles to the dissolved water of the upper unit dissolving tank 110.

The air layer located at the upper end of the lowermost unit dissolving tank 110 is undissolved undissolved air in the circulating water. As the air is supplied to the dissolving water in the upper unit dissolving tank 110 through the diffuser hole 121, the air enters the circulating water. The opportunity to dissolve arises again. In this way, as the circulating water is supplied to the upper unit dissolving tank 110 through the diffuser hole 121, contact between the circulating water and the air is made again, and the air dissolution efficiency is improved. In addition, according to the method in which air is supplied to the upper unit dissolving tank 110 through the diffusion hole 121 having a certain diameter, the air is refined by the diffusion hole 121, and the air is dissolved due to the air refinement. Efficiency is improved.

In the upper unit dissolving tank 110, the process of dissolving the air supplied through the diffuser hole 121 into the circulating water proceeds, and the dissolved water generated in the process proceeds through the dissolving water supply pipe 130 provided on one side of the upper unit dissolution tank. It is supplied to the upper unit melting tank 110. At the same time, the non-zone air layer located at the upper end of the upper unit dissolving tank 110 is supplied to the dissolved water of the upper unit dissolving tank 110 thereon through the air pore 121 .

In this way, the dissolved water at a certain level is filled in the unit dissolving tank 110 of each stage, and the process of dissolving the air into the circulating water proceeds, and the generated dissolved water passes through the dissolving water supply pipe 130 to the upper unit dissolving tank 110. ), and at the same time, the non-zone air provided at the upper end of each unit dissolving tank 110 is supplied to the upper unit dissolving tank 110 and dissolved in the dissolved water filled in the upper unit dissolving tank 110.

The dissolution process in each unit dissolution tank 110 proceeds sequentially, and as the dissolution process in each unit dissolution tank 110 proceeds sequentially and repeatedly, in preparation for the circulating water containing the air initially supplied, the final discharge Air solubility of dissolved water is improved.

As described above, in the air dissolving device according to an embodiment of the present invention, the air-containing circulating water sequentially passes through the plurality of unit dissolving tanks 110 arranged in the vertical direction, and the air is dissolved in the circulating water. Accordingly, it is possible to secure the residence time of circulating water and air, and in addition, the beauty zone air is supplied to the unit dissolving tank 110 at the top through the diffuser 121 and dissolved again, thereby inducing refinement of the air. It is possible to improve air dissolution efficiency by inducing re-contact between circulating water and air.

On the other hand, a pressure holding member in the form of an orifice pipe or a bushing is provided in the dissolved water discharge pipe 13 provided on one side of the uppermost unit dissolving tank 110 and discharging the dissolved water of the uppermost unit dissolving tank 110 to the outside. That is, an orifice pipe or a bushing is provided in the dissolved water discharge pipe 13, and the loss of pressure inside the dissolution tank 10 is suppressed by allowing the dissolved water to be discharged through the orifice pipe or the bushing. While high-pressure circulating water and air, for example, 5-7 bar air and 3-5 bar circulating water are supplied to the inside of the dissolving tank 10, a partial pressure drop occurs outside the dissolved water discharge pipe 13 and the dissolved water is discharged. In the process, the pressure inside the dissolution tank 10 may be lost. By providing an orifice tube or a pressure holding member in the form of a bushing in the dissolution pipe 13, the pressure inside the dissolution tank 10 is lost in the process of discharging the dissolved water. can prevent it from happening.

In the above-described embodiment, the melting bath 10 may be configured in a rectangular parallelepiped shape (see FIG. 1) or a cylindrical shape (see FIG. 2). In both cases, the dissolving process of air proceeds according to the above-described principle. When the dissolving tank 10 is configured in a cylindrical shape, a swirling flow of the dissolving water may be additionally induced. When the dissolving tank 10 has a rectangular parallelepiped shape, the dissolving water is convected from the first end side to the second end side of the unit dissolving tank 110, whereas when the dissolving tank 10 has a cylindrical shape, it passes through the dissolving water supply pipe 130. When the dissolved water is supplied to the unit dissolving tank 110, the dissolving water causes a swirl flow in the unit dissolving tank 110 as the unit dissolving tank 110 has a cylindrical shape. This swirling flow acts as a factor to increase the air melting efficiency. Here, when the dissolving bath 10 has a cylindrical shape, the dissolving bath separating plate 120 has a disc shape.

In addition to the configuration described above, a water level control vent pipe 14 is provided on one side of the uppermost unit dissolving tank 110 to adjust the level of the dissolved water in each unit dissolving tank 110 and to discharge unexisted air. When the water level of the uppermost unit melting tank 110 is below a certain level, the water level control vent pipe 14 is opened to discharge air, thereby raising the level of the dissolved water and maintaining the water level of the uppermost unit melting tank 110 at a certain level. When the water level of the dissolving tank 110 exceeds a certain level, the vent pipe 14 for adjusting the water level is blocked so that the beauty zone container is filled at the upper end of the uppermost unit dissolving tank 110 to lower the water level of the uppermost unit dissolving tank 110. The water level can be maintained at a certain level. In addition, a drain pipe 15 for discharging dissolved water for the purpose of maintenance may be provided on one side of the lowermost unit dissolving tank 110 .

10: melting tank 11: circulating water supply pipe
12: air supply pipe 13: dissolved water discharge pipe
14: water level control vent pipe 15: drain pipe
110: unit melting tank
120: dissolving tank separator 121: acid air hole
130: dissolved water supply pipe 131: dissolved water inlet hole
132: melted water outlet hole

Claims (7)

A melting tank providing a space in which the air melting process proceeds;
Dissolving tank separators spaced apart and disposed in the vertical direction in the dissolving tank to spatially divide the dissolving tank into a plurality of unit dissolving tanks;
A dissolved water supply pipe for upwardly moving the dissolved water in the lower unit dissolving tank to the neighboring upper unit dissolving tank; and
It is made to include; a plurality of acid pores provided in the dissolving tank separator plate,
The lower unit dissolving tank is filled with dissolved water at a certain level, and the air layer that is not dissolved in the circulating water is located above the level of the dissolved water. It is re-dissolved in the dissolved water filled in the unit dissolving tank,
When the circulating water containing air is supplied to the lowermost unit dissolving tank, the circulating water containing air is filled to a certain level, and the air is dissolved in the circulating water to produce dissolved water. It is supplied to the adjacent upper unit melting tank,
The dissolved water of each unit dissolving tank is supplied to the adjacent upper unit dissolving tank through the dissolving water supply pipe. An air dissolving device characterized in that it is dissolved by being supplied with dissolving water.
delete The method of claim 1, wherein a vent pipe for adjusting the water level is provided on one side of the uppermost unit melting tank to discharge unexisted air while adjusting the level of the dissolved water in each unit melting tank,
If the water level of the top unit melting tank is below a certain level, the water level control vent pipe is opened and the level of the dissolved water rises. An air melting device characterized in that the water level is lowered.
The method of claim 1, wherein a dissolved water discharge pipe for discharging the dissolved water of the uppermost unit dissolving tank to the outside is provided on one side of the uppermost unit dissolving tank,
An air dissolving device characterized in that a pressure holding member composed of an orifice pipe or a bushing is provided in the dissolved water discharge pipe, and the dissolved water is discharged through the pressure holding member to prevent loss of pressure inside the dissolution tank.
The method of claim 1, wherein the dissolving water supply pipe of the even-stage unit dissolving tank is provided on the first end side of the unit dissolving tank, and the dissolving water supply pipe of the odd-end unit dissolving tank is provided on the second end side of the unit dissolving tank, and the first end side and the second dissolving tank The one side is both ends of the unit melting tank,
A dissolved water inlet hole is provided at one side of the dissolved water supply pipe, and a dissolved water outlet hole is provided at an upper end of the dissolved water supply pipe to transfer the dissolved water moved upward along the dissolved water supply pipe to a neighboring upper unit dissolving tank,
The air dissolving device, characterized in that the dissolving water outlet hole is arranged in a horizontal direction.
The air dissolving device according to claim 1, wherein the dissolving tank has a rectangular parallelepiped shape or a cylindrical shape.
The method of claim 6, wherein when the dissolving bath has a cylindrical shape, the dissolving bath separating plate forms a disk shape,
The dissolved water outlet hole connected to the dissolved water supply pipe is arranged in a horizontal direction on the dissolving tank separator plate and arranged in an oblique shape toward the circumference of the dissolving tank separator plate to induce a swirling flow of the dissolved water.

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