KR20230040168A - Pressurized air lifting system - Google Patents

Abstract

The present invention comprises: a stirring tank in which raw water is introduced and flocs are formed through stirring; a reaction tank that receives the raw water, in which the flocs are formed, from the stirring tank to induce the attachment of the flocs and microbubbles; a flotation tank in which the flocs to which the microbubbles are attached are introduced from the reaction tank together with raw water to be floated; a flotation sludge tank in which the flocs floated by a scraper are guided at one side of the flotation tank; a storage tank into which the treated water from which the flocs have been removed from the flotation tank is introduced to be stored; and a dissolution device that receives the treated water from the storage tank and receives air from an air supply device to dissolve the air in the treated water and then supplies the dissolved water to the reaction tank. Floating substances can be efficiently removed by improving microbubble generation efficiency.

Description

Pressurized air lifting system

The present invention relates to a system capable of increasing the removal efficiency of suspended solids by increasing the efficiency of generating microbubbles by continuously recirculating the treated water through air dissolved therein.

In general, water treatment devices are various devices for appropriately treating raw water in order to purify sewage, wastewater, and the like. This water treatment device includes a device for removing foreign substances mixed in raw water.

As one unit process for removing foreign substances, there is a Dissolved Air Floatation (DAF) method. Dissolved air flotation is a device that mixes a coagulant with the raw water to be treated to coagulate foreign substances contained in the raw water and floats and removes the coagulated foreign substances together with microbubbles.

is being applied properly.

As an example of this technology, Korean Patent Registration No. 10-2253000 injects microbubbles into the influent, which is the water to be treated, in a contact zone, and in a separation zone, the microbubbles and contaminants in the influent are combined. The above of Dissolved Air Flotation (DAF) to float the aggregates to the top of the separation tank, remove the aggregates floated in the collection chamber in the form of sludge, and generate the final treated discharge water. In the header provided in the separation tank,

The header is installed in the lower space in the separation tank, collects the treated water drawn to the lower space in the separation tank after the aggregate is removed, and discharges it to a unit downstream of the separation tank. The header provided in is presented.

However, in the case of the above technology, there is a problem in that it is difficult to improve the flotation efficiency by generating enough microbubbles.

Republic of Korea Patent Registration No. 10-1628678

The present invention has been made to solve the above problems, and relates to a system capable of improving the efficiency of the entire process by increasing the efficiency of generating microbubbles by increasing the air dissolution rate in treated water.

As a means for solving the above problems, the pressurized air flotation system of the present invention (hereinafter referred to as "the system of the present invention") includes a stirring tank in which raw water is introduced and flocs are formed through stirring; a reaction tank receiving raw water in which floes are formed from the stirring tank and inducing adhesion of flocs and microbubbles; a flotation tank in which the floc to which the microbubbles are attached is introduced from the reaction tank together with the raw water and floated; a flotation sludge tank for guiding floes floated by a scraper at one side of the flotation tank; a storage tank into which the treated water from which the floc is removed from the flotation tank is introduced and stored; and a dissolving device for supplying the dissolved water to the reaction tank after receiving treated water from the storage tank and receiving air from the air supply device so that the air is dissolved in the treated water.

As an example, the dissolved device includes an outer tube portion having an inlet line through which treated water and air flow into one side, and a pressurized space formed outside the outer tube portion in the shape of a fallopian tube whose diameter increases in the opposite direction to the inlet line. It is characterized in that it includes a partition tube in which a turning space is formed on the inside, a flow path through which the pressurization space and the turning space communicate with each other is formed at the end, and a discharge line passing through the outer tube portion is formed in the direction in which the inlet line is formed.

As an example, the dissolved device has an inclined gradient, an air layer is formed at the upper end, and an inlet line through which treated water and air are introduced is formed at the lower part of the air layer. It is characterized in that it includes an inclined pipe portion in which a discharge line is formed, and a level adjusting tool for adjusting the formation position of the air layer to control exposure of the inlet line to the air layer.

As an example, a pressure space is formed on the outside and a turning space is formed on the inside in the shape of a fallopian tube whose diameter increases in the opposite direction to the inlet line inside the inclined pipe portion, and a flow path in which the pressure space and the turning space communicate with each other is formed at the end. It is characterized in that an inner partition pipe in which a discharge line penetrating the inclined pipe portion is formed in the direction in which the inlet line is formed is further included.

As an example, a plurality of cleaving protrusions are further formed on the inner periphery of the inner compartment.

As an example, the inlet line is connected to the inlet line at the end and has an inner discharge pipe in which a plurality of discharge holes are formed, and an outer discharge passage in which the inner discharge pipe is embedded and the diameter is reduced at the end of the inner discharge pipe. It is characterized in that the dissolved nozzle including the discharge pipe is further configured.

As an example, the floating sludge tank is composed of an inclined surface on which a slope is formed in one direction on the lower surface, and a sludge discharge line is formed at the lower end, and the floating sludge tank and the storage tank share a side wall while forming a plurality of overflow holes at the upper end of the side wall. It is characterized in that the treated water from which the floc is removed flows into the floating sludge tank through the overflow hole.

As an example, a collecting part is further configured at the lower end of the lower surface, and the water collecting part collects moisture on the outside and has a water discharge line for discharging the collected water. It is characterized in that it includes a sludge strainer in which a mixture of treated water and sludge is introduced, passes moisture, filters out the sludge, and forms a sludge discharge line passing through the water collection unit.

As described above, the system of the present invention has the advantage of increasing the removal efficiency of suspended solids by increasing the efficiency of generating microbubbles by allowing recirculation to be continuously performed through dissolved air in the treated water.

1 is a diagram showing the system of the present invention;
2 is a diagram showing an embodiment of a dissolving device, which is one component of the present invention;
3 is a view showing another embodiment of a dissolving device, which is one component of the present invention;
4 is a view showing another embodiment of the example shown in FIG. 3;
5 is a view showing an embodiment of a floating sludge tank and a storage tank, which are one component of the present invention;
6 is a view showing a dissolved nozzle as one component of the present invention.

Hereinafter, the configuration and operation of the present invention will be described in more detail based on the accompanying drawings. In describing the present invention, the terms or words used in this specification and claims are based on the principle that the inventor can appropriately define the concept of the term in order to best describe his or her invention. should be interpreted as a meaning and concept that corresponds to the technical idea of

As shown in FIG. 1, the system 1 of the present invention includes a stirring tank 2 in which raw water is introduced and flocs are formed through stirring; a reaction tank (3) receiving the raw water in which the floes are formed from the stirring tank (2) and inducing adhesion of the floes and microbubbles; a flotation tank (4) in which the floc to which the microbubbles are attached from the reaction tank (3) flows in together with raw water and floats; a flotation sludge tank 5 for guiding floes floated by the scraper 41 at one side of the flotation tank 4; a storage tank (6) into which the treated water from which the floc is removed from the flotation tank (4) is introduced and stored; Dissolution devices (7, 8) supplying the dissolved water to the reaction tank (3) after receiving treated water from the storage tank (6) and receiving air from the air supply device (10) to dissolve the air in the treated water; It is characterized by including.

The agitation tank 2 is to form flocs by coagulating the floating matter contained in the raw water in a manner in which raw water containing suspended matters is introduced, a coagulant is added to the raw water, and agitation is performed.

Although not shown in the drawing, the stirring tank 2 is provided with a chemical supply means for injecting a chemical such as a coagulant and an agitator (drawing number not shown) for agitating raw water and the coagulant.

The reaction tank 3 is configured at a position adjacent to the stirring tank 2 so as to receive the raw water containing the floc from the stirring tank 2, and as shown in the drawing, while sharing the side wall, reference numbers are not shown, but the bottom of the side wall It is configured to communicate. A dissolved water injection device 31 is configured in the reaction tank 3 so that the dissolved water is injected from the dissolved devices 7 and 8 . Here, the dissolved water is saturated water in which compressed air is dissolved, and when this saturated water is discharged to the reaction tank 3, microbubbles are formed, and the microbubbles thus formed are attached to the flocs to induce floating of the flocs.

The flotation tank 4 is configured in association with the reaction tank 3 so as to receive the floc to which the microbubbles are attached from the reaction tank 3, and the floc flowing into the flotation tank 4 floats to the surface of the water by the microbubbles.

In the flotation tank 4, a scraper 41 is installed to be located at the upper end of the floatation tank 4, and the floc floating to the surface is discharged to the flotation sludge tank 5 configured on one side of the floatation tank 4.

In the storage tank 6, the treated water from which the floc is removed from the flotation tank 4 is introduced and stored while being discharged or circulated to the dissolved devices 7 and 8.

On the other hand, the floating sludge tank 5 shown in FIG. 6 is composed of an inclined surface on which the lower surface 51 is inclined in one direction, and a sludge discharge line 52 is formed at the lower end, and the floating sludge tank 5 and the In the storage tank 6, a plurality of overflow holes 53 are formed at the upper end of the side wall while sharing the side wall, and the treated water from which the floc is removed flows into the floating sludge tank 5 through the overflow holes 53. are presenting

This is to control the deposition of the sludge (S) in the floating sludge tank (5), and when the treated water stored in the storage tank (6) exceeds a certain level without a separate watering means, the overflow hole (53) Through this, the treated water and the sludge (S) overflowed by the inclination of the lower surface (51) of the floating sludge tank (5) are discharged to the sludge discharge line (52).

In addition, a collecting unit 54 is further configured at the lower end of the lower surface 51, and the collecting unit 54 collects moisture on the outside and has a water discharge line 541-1 for discharging the collected water. The water collecting part 541 communicates with the lower surface 51 inside the water collecting part 541, and the treated water and sludge mixture flows in, passes the water, filters the sludge, and penetrates the water collecting part 541 It is characterized in that it includes a sludge filter network portion 542 in which a sludge discharge line 52 is formed.

The overflowed treated water and sludge mixture slides along the slope of the lower surface 51 and flows into the sludge filter 542, and the sludge filters the sludge by permeating moisture in the sludge filter 542. It is to be discharged to the outside through the sludge discharge line 52.

The type of the sludge strainer 542 is not limited as long as it is made of a material that transmits moisture. For example, a mesh net may be applied.

Moisture permeated through the sludge filtering net 542 is collected in the water collecting unit 541 and discharged to the outside through the water discharging line 541-1.

By lowering the water content in the discharged sludge configured as described above, it is possible to reduce the load of the subsequent sludge treatment process.

Meanwhile, in the present invention, two embodiments of dissolving devices 7 and 8 are proposed.

The dissolved device 7 shown in FIG. 2 includes an outer pipe portion 71 having an inlet line 711 through which treated water and air flow into one side, and a portion of the inlet line 711 inside the outer pipe portion 71. In the shape of a fallopian tube whose diameter increases in the opposite direction, a pressurized space 721 is formed on the outside, a turning space 722 is formed on the inside, and a passage 723 in which the pressurized space 721 and the turning space 722 communicate with each other at the end Is formed and characterized in that it includes a partition pipe 72 in which a discharge line 724 passing through the outer pipe portion 71 is formed in the direction in which the inlet line 711 is formed.

The inlet line 711 is connected to the storage tank 6 so that the treated water is circulated from the storage tank 6, and as shown in the drawing, it is also connected to the air supply device 10 so that air is mixed with the circulated treated water. By doing so, the treated water and air are introduced into one side of the outer tube part 71.

A compartment tube 72 is formed inside the outer tube portion 71 so that a pressurized space 721 outside the compartment tube 72 and a turning space 722 inside the compartment tube 72 are formed. As shown, the treated water and air introduced into the outer pipe 71 form a vortex W1 in the pressurized space 721 and flow to one side. The vortex and the pressurized force make it easy to dissolve air in the treated water , Dissolved water that has passed through the pressurized space 721 flows into the swirling space 722 through the passage 723 to form a vortex W2 and flows to the other side. It is to facilitate the dissolution of air in water, and to increase the dissolution rate by taking a long contact time by turning. Through this process, the dissolved water becomes saturated water as mentioned above and flows into the reaction tank 3 through the discharge line 724.

As another example, as shown in FIG. 3, the dissolving device 8 has an air layer 812 formed at an upper end with an inclined gradient as shown in FIG. Inclined pipe part 81 in which an inlet line 811 is formed and a discharge line 813 through which dissolved water is discharged is formed at a lower part, and exposure of the inlet line 811 to the air layer 812 is controlled. It is characterized in that it includes a level adjusting sphere 82 for adjusting the formation position of the air layer 812 to do so.

In the treated water and air introduced through the inlet line 811 in the inclined pipe part 81, the treated water has a downward force due to its own weight and the air has an upward force. It acts to increase the solubility rate by mutual collision. In this case, although not shown in the drawing, it is reasonable that the inlet line 811 is formed on one side of the inclined pipe part 81 so that a vortex is formed.

In this process, the air layer 812 is formed at the upper end of the inclined pipe part 81 by the air that is not dissolved, and the pressure inside the inclined pipe part 81 is controlled by the air layer 812 thus formed. . That is, the air layer 812 is formed above the inlet line 811 by the level adjusting device 82 so that the inclined pipe part 81 sufficiently dissolves air in the treated water under a certain pressure.

The level adjuster 82 can be applied to various known technologies. For example, the height at which the air layer 812 is formed is adjusted by interlocking with a pressure sensor to insert air into and subtract it from the air layer 812.

In addition, in FIG. 4, a pressure space 831 is formed on the outside and a turning space 832 is formed on the inside in the shape of a fallopian tube whose diameter increases in the opposite direction to the inlet line 811 inside the inclined tube part 81, and the end An internal partition pipe in which a flow path 833 communicating between the pressurized space 831 and the turning space 832 is formed and a discharge line 813 penetrating the inclined pipe portion 81 is formed in the direction in which the inlet line is formed ( 83) is presented as an example of further inclusion. That is, the above-mentioned pressure and vortex are formed inside the inclined pipe part 81 to further double the dissolved rate. Since the operation mechanism of the inclined pipe part 81 and the inner partition pipe 83 is the same as the above-mentioned, a detailed description thereof will be omitted.

However, in this embodiment, as mentioned above, in the pressurized space 831, a downward force acts on the treated water, but an upward force acts on the air, so that the dissolution rate is further improved by collision, and in the swirling space 832 As the treated water with the downward force acts upward, the collision with air is less likely to occur, but the dissolved rate increases as the turning time becomes longer.

In addition to this, in this embodiment, a plurality of cleaving protrusions 834 are further configured on the inner periphery of the inner compartment 83 so that the dissolved water forms a vortex W2 while collision by the cleaving protrusions 834 is added. This is to further increase the solubility.

In addition, in the present invention, in order to further increase the dissolved rate, as shown in FIG. 5, the dissolved nozzles 9 are configured in the inlet lines 711 and 811, so that the dissolved nozzles 9 when the treated water and the air flow in, respectively. An example of further doubling the dissolved rate in the dissolving devices 7 and 8 is presented.

The dissolved nozzle 9 is connected to the inflow lines 711 and 811 and has an internal discharge pipe 91 in which a plurality of discharge holes 911 are formed, and the internal discharge pipe 91 is embedded in the internal discharge pipe. It is characterized in that it includes an external discharge pipe 92 in which a discharge passage 921 having a smaller diameter is formed at the end of the (91).

Preferably, the discharge hole 911 is formed in a spiral shape, so that treated water and air are discharged while being split by the discharge hole 911, and at the same time, a vortex is formed by the shape of the discharge hole 911, so that dissolved in the discharge process The treated water and air discharged in this way are pressurized while passing through the discharge passage 921 having a smaller diameter, thereby increasing the dissolved water. When flowing into the inclined pipe part 81, fine bubbles are formed.

Through the above description, those skilled in the art will know that various changes and modifications are possible without departing from the technical idea of the present invention. Therefore, the technical scope of the present invention is not limited to the contents described in the detailed description of the specification, but should be defined by the claims.

1: the present invention 2: stirring tank
3: reaction tank 4: floating tank
5: floating sludge tank 6: storage tank
7: dissolved device 8: dissolved device
9: dissolved nozzle 10: air supply device

Claims (8)

An agitation tank in which raw water is introduced and flocs are formed through agitation;
a reaction tank receiving raw water in which floes are formed from the stirring tank and inducing adhesion of flocs and microbubbles;
a flotation tank in which the floc to which the microbubbles are attached is introduced from the reaction tank together with the raw water and floated;
a flotation sludge tank for guiding floes floated by a scraper at one side of the flotation tank;
a storage tank into which the treated water from which the floc is removed from the flotation tank is introduced and stored;
a dissolved device for supplying the dissolved water to the reaction tank after receiving treated water from the storage tank and receiving air from the air supply device to dissolve the air in the treated water;
Pressurized air flotation system comprising a.
According to claim 1,
The dissolved device,
An outer tube portion having an inlet line through which treated water and air are introduced is formed on one side, and a pressure space is formed on the outside and a turning space is formed on the inside in the shape of a fallopian tube whose diameter increases in the opposite direction to the inlet line inside the outer pipe portion. And the pressurized air flotation system characterized in that it comprises a compartment pipe in which a flow path communicating with the pressurized space and the turning space is formed at the end and a discharge line passing through the outer pipe portion is formed in the direction in which the inlet line is formed.
According to claim 1,
The dissolved device,
An inclined pipe portion with an air layer formed at the upper end with an inclined gradient, an inlet line through which treated water and air are introduced at the lower part of the air layer at the upper part, and a discharge line through which dissolved water is discharged at the lower part located at the bottom. And, the pressurized air flotation system comprising a level adjuster for adjusting the formation position of the air layer to control exposure of the inlet line to the air layer.
According to claim 3,
Inside the inclined pipe part, a pressure space is formed on the outside and a turning space is formed on the inside in the shape of a fallopian tube whose diameter increases in the opposite direction to the inlet line, and a flow path communicating between the pressurized space and the turning space is formed at the end, and the inlet line The pressurized air flotation system, characterized in that the inner compartment pipe in which the discharge line passing through the inclined pipe portion is formed in the formed direction is further included.
According to claim 4,
Pressurized air flotation system, characterized in that a plurality of cleaving projections are further configured on the inner periphery of the inner compartment.
According to claim 2 or 3,
The inlet line is connected to the inlet line at the end and includes an inner discharge pipe in which a plurality of discharge holes are formed, and an external discharge pipe in which the discharge pipe is embedded and a discharge passage having a smaller diameter is formed at the end of the discharge pipe A pressurized air flotation system, characterized in that the dissolved nozzle is further configured.
According to claim 1,
The floating sludge tank is composed of an inclined surface on which a slope is formed in one direction on the lower surface, and a sludge discharge line is formed at the lower end,
The floating sludge tank and the storage tank share a side wall and a plurality of overflow holes are formed at the upper end of the side wall so that the treated water from which the floc is removed flows into the floating sludge tank through the overflow hole. Pressurized air flotation system.
According to claim 7,
A collecting part is further configured at the lower end of the lower surface, and the water collecting part collects moisture on the outside and has a water discharge line for discharging the collected water. and a sludge filter net in which a sludge mixture is introduced, passes moisture, filters the sludge, and forms a sludge discharge line penetrating the water collecting unit.

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