KR101367188B1 - Ultrasonic generator, wastewater treatment systems and wastewater treatment method using the same - Google Patents

Abstract

An ultrasonic generator, a wastewater treatment system, and a wastewater treatment method using the same are disclosed. This wastewater treatment system includes a screen tank, a collection tank for collecting wastewater, a reaction tank for agglomeration of organic matter in the wastewater, a first precipitation tank for collecting supernatant water by removing sediment, an aeration tank for injecting microorganisms to remove organic matter, and sedimentation. And a second settling tank for removing the microorganisms and a disinfecting tank for generating the ultrasonic wave to remove the bacteria. As a result, it is possible to prevent the destruction of the aquatic ecosystem due to the discharge of toxic substances caused by the use of unnecessary drugs, to prevent the transmission of waterborne infections caused by bacteria and pests, and to reduce the cost of using the drugs.

Description

Ultrasonic generator, wastewater treatment system and wastewater treatment method using the same {Ultrasonic generator, wastewater treatment systems and wastewater treatment method using the same}

The present invention relates to an ultrasonic wave generator, a wastewater treatment system, and a wastewater treatment method using the same. More specifically, an ultrasonic wave generator, a wastewater treatment system for removing bacteria, waterborne infectious agents and pests of wastewater by effectively using ultrasonic waves. And it relates to a wastewater treatment method using the same.

Human beings have made rapid industrial development, but they have neglected to worry about the environmental problems behind them. As a result, various environmental problems have emerged in recent years, and water pollution is one of human problems.

Water treatment is divided into a primary treatment step for carrying out physical / chemical treatment and a secondary treatment step for carrying out biological treatment.

Physical treatment is a treatment method for filtering wastewater by filtering the waste water with a mesh screen. The chemical treatment is a treatment method in which an inorganic flocculant is administered to the wastewater from which contaminants have been filtered to aggregate and precipitate organic matter and suspended matter in the wastewater.

Wastewater, which has undergone such physical / chemical primary treatment, is subjected to biological secondary treatment to remove organic matter using microorganisms.

In general, the waste water after the first or second treatment is completed is moved to a disinfection tank or a discharge tank, and the process involves removing microorganisms through post-treatment with hypochlorite or chlorine before being discharged into the natural water system. This treatment process causes toxic substances to be released into the natural water system by disinfectant, etc., which adversely affects the water ecosystem. In order to solve this problem, methods for removing bacteria using ultrasound have been proposed.

When ultrasonic waves are irradiated, a large amount of cavities are generated and the cavitation bubbles are under negative pressure and are destroyed to generate shock waves. In this process, bacteria or the like are removed or sterilized by high energy of high temperature and high pressure.

However, the conventional water treatment using ultrasonic waves has a problem that it is not effective for removing microorganisms because the ultrasonic waves are irradiated for a short time while the treated water flows from the discharge tank.

Accordingly, the search for a method for effectively removing microorganisms through ultrasonic irradiation is required.

The present invention has been made to solve the above problems, an object of the present invention, the ultrasonic generator for allowing the user to arbitrarily vary the flow path in the disinfection tank or discharge tank so that the waste water is exposed to the ultrasonic wave can be long. The present invention provides a wastewater treatment system and a wastewater treatment method using the same.

Waste water treatment system according to an embodiment of the present invention for achieving the above object, the screen tank for filtering contaminants from the waste water; A collecting tank for collecting the wastewater from which the contaminants are filtered out of the screen tank; A reaction tank for aggregating organic matter and suspended matter in the waste water by reacting the waste water conveyed from the sump with a chemical; A first precipitation tank for collecting supernatant water by removing the precipitate precipitated by aggregation of the organic matter and suspended matter; An aeration tank for growing microorganisms so that the organic matter is removed from the supernatant transferred from the first precipitation tank; A second precipitation tank for removing or conveying activated sludge precipitated by the organic matter; And a disinfection tank for generating the ultrasonic wave to remove the bacteria contained in the treated water transferred from the second precipitation tank, wherein the disinfection tank includes an inlet for introducing the treated water transferred from the second precipitation tank; An outlet for discharging the treated water transferred from the second settling tank to the outside; And a plurality of partition walls for forming a flow path through which the treated water transferred from the second settling tank moves from the inlet to the outlet.

Here, the plurality of partitions may be configured such that one side and the other side are alternately opened for each partition wall in the disinfection tank so that the flow path is formed in a zigzag.

Further, each partition wall may be composed of a plurality of ultrasonic generators that can be assembled.

In addition, the ultrasonic wave generator may have a rectangular shape, and may include a ultrasonic wave generator and a switch unit for manipulating operations of the ultrasonic wave generators provided on the four surfaces on the remaining four surfaces except the upper and lower surfaces. .

In addition, when the ultrasonic wave generating device is assembled such that the first surface of the four surfaces is adjacently coupled to another ultrasonic wave generating device, the ultrasonic wave generating unit provided on the first surface may not operate by the assembly. The addition can be controlled.

On the other hand, the ultrasonic wave generating apparatus for removing bacteria from the waste water according to an embodiment of the present invention for achieving the above object, each of the other four surfaces except for the top and bottom surfaces to be assembled and assembled with other ultrasonic generators A fastening part provided; Ultrasonic generators provided on the four surfaces; And the ultrasonic generator does not operate when the other ultrasonic generator is assembled to the fastening unit, and the ultrasonic generator operates on the four sides when the other ultrasonic generator is not assembled. It includes a switch unit.

On the other hand, waste water treatment method according to an embodiment of the present invention for achieving the above object, the step of filtering the contaminants from the waste water; Collecting the wastewater from which the contaminants are filtered; Reacting the collected waste water with a chemical to agglomerate organic matter and suspended matter in the waste water; Collecting the supernatant by removing the precipitate precipitated by aggregation of the organic matter and the suspended matter; Growing microorganisms to remove the organic matter from the collected supernatant; Removing or conveying activated sludge precipitated by the organic matter; And generating ultrasonic waves to remove residual bacteria.

As the water treatment proceeds using ultrasonic waves in this way, it prevents the destruction of the aquatic ecosystem due to the discharge of toxic substances caused by the use of unnecessary chemicals, prevents the transmission of waterborne infections caused by bacteria and pests, and the cost of using the chemicals. The occurrence can be reduced. In addition, it is possible to save energy by preventing unnecessary ultrasonic irradiation, and to form a flow path due to the assembly of the user, it is possible to efficiently ultrasonic irradiation in a smaller amount, and the partition wall is not limited to the size or shape of the sterilization tank. Can be formed.

1 is a view showing a wastewater treatment system according to an embodiment of the present invention,
2 is a view showing a perspective view of the disinfection tank 700 according to an embodiment of the present invention,
3 is a view showing a plan view of the disinfection tank 700 according to an embodiment of the present invention,
4 is a plan view of the ultrasonic generating apparatus 800 according to an embodiment of the present invention.
5 is a perspective view of the ultrasonic generator 800,
6 is a view showing a state in which a plurality of ultrasonic generators 800 are coupled, and,
7 is a flowchart illustrating a wastewater treatment method according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a view showing a wastewater treatment system according to an embodiment of the present invention. The wastewater treatment system according to the present embodiment includes a screen tank 100, a collection tank 200, a reaction tank 300, a first precipitation tank 400, a concentration tank 450, an aeration tank 500, a second precipitation tank 600, and It is built with a disinfection tank 700.

The screen tank 100 serves to remove the contaminants introduced with the raw waste water through the screen when the raw waste water is introduced.

The sump tank 200 temporarily stores the waste water from which the contaminants are removed from the screen tank 100 and adjusts the flow rate for treatment in the stage after the sump tank 200.

Reactor 300 is also referred to as a chemical agglomeration reaction tank, by reacting the waste water transported from the sump tank 200 with the chemical, so that the organic matter and solids contained in the waste water is aggregated.

The first settling tank 400 to precipitate the sludge agglomerated organic matter and solids, so that the sediment and the supernatant.

Aeration tank 500 is based on the supernatant transferred from the first settling tank 400, so that the digestion and culture / propagation of organic matter by aerobic microorganisms are made.

The second precipitation tank 600 allows the activated sludge and the supernatant formed by the organic matter to be digested.

The concentration tank 450 treats the precipitate precipitated in the first precipitation tank 400 and the activated sludge precipitated in the second precipitation tank 700.

The disinfection tank 700 is treated in the second precipitation tank 700 to remove bacteria and pests (hereinafter, collectively referred to as 'bacteria') in the treated water transferred from the second precipitation tank 700. In particular, the disinfection tank 700 is provided with an ultrasonic wave generator to be described later to remove the bacteria, to improve the degree of exposure of the bacteria to the ultrasonic wave to provide an ultrasonic generator capable of variable flow path to enable efficient ultrasonic irradiation.

Hereinafter, with reference to FIGS. 2 to 3 will be described with respect to the ultrasonic wave generation device provided in the disinfection tank 700 and the resulting flow path change.

2 is a view showing a perspective view of the disinfection tank 700 according to an embodiment of the present invention. As shown, the disinfection tank 700 is composed of an inlet 710, a plurality of partitions 720, and an outlet 730.

The inlet 710 is treated in the second settling tank 600 to serve as a passage through which the treated water transferred from the second settling tank 600 flows, and the outlet 730 is a treatment received from the second settling tank 600. Ultrasonic water is irradiated to serve as a passage for discharging the treated water from which bacteria and the like have been removed.

Inlet 710 is assumed to be provided on the upper left side, based on the left side of the disinfection tank 700, but may be provided in a different position, the outlet 730 is also provided in a different position than shown Can be.

On the other hand, as shown in the plurality of partitions 720, one side and the other side for each partition 720 in the disinfection tank 700, so that the flow path to move the treated water flowing through the inlet 710 is formed in a zigzag. It can be configured in an alternately open form.

In this way, since the ultrasonic waves are irradiated from each partition wall 720, the extent to which the treated water is exposed to the ultrasonic waves can be increased due to the zigzag flow path.

Hereinafter, the shape of the flow path will be described in more detail with reference to FIG. 3. 3 is a view showing a plan view of the disinfection tank 700 according to an embodiment of the present invention.

The disinfection tank 700 is provided so that the direction in which the plurality of partition walls 720 are opened alternates with each other. As a result, the flow path 740 is formed in a zigzag form as shown.

 In the illustrated example, the openings are provided in the order of the lower side, the upper side, the lower side, and the upper side, from the left side to the right side so that the flow path 740 is formed according to the position of the opening, but the opening can be changed according to the user's convenience. Of course.

In particular, in FIG. 3, it is assumed that the inlet part 710 is provided at the upper left side and the outlet part 730 is provided at the lower right side, so that the order of the lower side, the upper side, the lower side, and the upper side is increased in order to increase the ultrasonic exposure degree of the treated water. Furnace opening is provided is provided, according to the position of the inlet 710, the position of the outlet 730 and the size or shape of the disinfection tank 700, and of course it can be implemented to be freely located. .

In addition, since each partition wall 720 is formed by assembling a plurality of ultrasonic wave generators 800, not only the position of the opening opening, but also the shape and arrangement of each partition wall 720 may be freely modified according to the user's convenience. Do. For description thereof, reference will be made to FIGS. 4 to 6.

4 is a view showing a plan view of the ultrasonic generator 800 according to an embodiment of the present invention, Figure 5 is a view showing a perspective view of the ultrasonic generator 800, Figure 6 is a plurality of ultrasonic generators 800 is a view showing a combined state.

As shown in FIG. 4, the ultrasonic wave generator 800 includes a body part 810, a first side fastening part 820, a first side switch part 825, a second side fastening part 830, and a second part. The side switch portion 835, the third side fastening portion 840, the third side switch portion 835, the fourth side fastening portion 850, and the fourth side switch portion 855.

In addition, as illustrated in FIG. 5, the ultrasonic generator 800 further includes ultrasonic generators 860 and 870 on each surface thereof. For example, a first side ultrasonic generator (not shown) is provided on the first side of the ultrasonic generator 800, a second side ultrasonic generator 870 is provided on the second side, and a third side ultrasonic generator is disposed on the third side ( 860 and a fourth side ultrasonic generator (not shown) are provided on the fourth side. The ultrasonic generators 860 and 870 may be configured in plural as shown.

The body 810 is configured in a rectangular shape, and the fastening parts 820, 830, 840, and 850 are connected to the remaining four surfaces except for the top and bottom surfaces of the body 810.

The fastening parts 820, 830, 840, and 850 are parts for allowing the ultrasonic generator 800 to be assembled and connected with other ultrasonic generators. For example, as shown in FIG. 6, the upper fastening portion of the first ultrasonic generator is assembled with the lower fastening portion of the second ultrasonic generator, and the upper fastening portion of the second ultrasonic generator is lower than the third ultrasonic generator. Can be assembled with the fastening portion.

At the time of assembly, the lower fastening portion of the second ultrasonic generator is positioned in the space between the body portion and the upper fastening portion of the first ultrasonic generator, and conversely, the upper fastening portion of the first ultrasonic generator is the second ultrasonic generator. It is located in the space between the body portion and the lower fastening portion.

In addition, as shown in Figures 2 and 3 will not necessarily be assembled and assembled in a straight form, it may be assembled in a 'b' shape or 'c' shape or the like. For example, when the assembly is connected in a 'b' shape, the upper fastening portion of the first ultrasonic generator is assembled and connected to the lower fastening portion of the second ultrasonic generator, and the left fastening portion of the second ultrasonic generator is the third ultrasonic wave generation. Can be assembled with the right fastening of the device.

Meanwhile, switch parts 825, 835, 845, and 855 are provided between the body part 810 and the fastening parts 820, 830, 840, and 850 on four sides. The switch units 825, 835, 845, and 855 detect the fastening through a method of being pressed by the fastening part of the other ultrasonic generator when the fastener is fastened with another ultrasonic generator.

In addition, the switch unit 825, 835, 845, 855 stops the operation of the ultrasonic generator corresponding to the detected portion when the fastening is detected. For example, when the upper fastening portion of the first ultrasonic generator is assembled with the lower fastening portion of the second ultrasonic generator, the switch provided on the lower side of the second ultrasonic generator may fasten the upper fastening portion of the first ultrasonic generator. In response, the switch provided on the upper side of the first ultrasonic wave generator recognizes the fastening of the lower fastening portion of the second ultrasonic wave generator. Therefore, the operation of the ultrasonic generator provided on the upper side of the first ultrasonic generator is stopped, and the operation of the ultrasonic generator provided on the lower side of the second ultrasonic generator is stopped.

That is, since the portion that is not exposed to the treated water due to the combination with other ultrasonic generators is an unnecessary portion of the irradiation of the ultrasonic wave, the switch unit 825, 835, 845, 855 detects this so that the ultrasonic wave of the portion is not irradiated. Will be done.

As a result, unnecessary ultrasonic irradiation can be prevented and energy saving can be achieved, and a flow path can be formed by user's assembly and combination, so that ultrasonic irradiation can be more efficient, and bulkheads can be formed regardless of the size or shape of the disinfection tank 700. I can make it.

7 is a flowchart illustrating a wastewater treatment method according to an embodiment of the present invention.

First, the screen tank 100 to filter the contaminants from the raw waste water using a mesh or the like (S910). Subsequently, the collection tank 200 temporarily stores wastewater from which the contaminants are removed from the screen tank 100 and adjusts the flow rate for treatment in the step after the collection tank 200 (S920).

In the reaction tank 300, chemicals are introduced into the waste water transferred from the sump tank 200, and the organic matter and solids contained in the waste water are aggregated (S930), and in the first precipitation tank 400, the waste water sludge in which the organic matter is aggregated is precipitated. , So that the sediment and the supernatant is separated so that the sediment is removed and the supernatant is collected (S940).

Subsequently, in the aeration tank 500, microorganisms are grown to digest and cultivate / grow the organics by aerobic microorganisms based on the supernatant water transferred from the first precipitation tank 400, and in the second precipitation tank 600, the organic matter is digested. Thus, the precipitated activated sludge and the supernatant are separated, so that the precipitated activated sludge is removed or returned (S960).

In the sterilization tank 700, in order to remove bacteria, ultrasonic waves are generated (S970).

As such, by proceeding with the water treatment using ultrasonic waves, it is possible to eliminate the ecotoxicity problem, and to reduce the drug and prevent water-borne infectious diseases.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood that the invention may be practiced. Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all aspects. In addition, the scope of the present invention is indicated by the following claims rather than the above detailed description. Also, all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

In particular, in the above, it is assumed that the partition wall 720 or the ultrasonic generator 800 is provided in the disinfection tank 700, but this is merely an example for convenience of description. Accordingly, the partition wall 720 or the ultrasonic wave generator 800 according to the present invention is provided in a collecting tank 200, a reaction tank 300, a precipitation tank 400, 600, or a discharge tank (not shown), instead of the disinfection tank 700. In this case, the technical spirit of the present invention may be applied as it is.

In addition, in the above, a total of four partitions 720 are provided, and each partition 720 includes eight ultrasonic generators 720 in total, and each ultrasonic generator 720 includes four ultrasonic generators 860. It is assumed to have a), but the specific number and location may be set differently.

In addition, in the above, it is assumed that the ultrasonic generator 720 has a specific shape through FIGS. 4 to 6, but this is also merely an example for convenience of description, and the described form is possible when the mutual assembly is possible. Even if it has a different form and will be considered to fall within the technical scope of the present invention.

In addition, in the above, it is assumed that the switch unit detects the assembly coupling by providing a separate switch unit, but not only when detecting the assembly coupling, but also whether the irradiation of the ultrasonic wave is controlled based on the on-off operation of the user. The technical idea of the can be applied as it is.

100: screen tank 200: water tank
300: reactor 400: first precipitation tank
450: concentration tank 500: aeration tank
600: second settling tank 700: disinfection tank

Claims (7)

Screen baths for filtering contaminants from wastewater;
A collecting tank for collecting the wastewater from which the contaminants are filtered out of the screen tank;
A reaction tank for aggregating organic matter and suspended matter in the waste water by reacting the waste water conveyed from the sump with a chemical;
A first precipitation tank for collecting supernatant water by removing the precipitate precipitated by aggregation of the organic matter and suspended matter;
An aeration tank for growing microorganisms so that the organic matter is removed from the supernatant transferred from the first precipitation tank;
A second precipitation tank for removing or conveying activated sludge precipitated by the organic matter; And
And an antiseptic tank for generating ultrasonic waves to remove bacteria contained in the treated water transferred from the second precipitation tank.
The disinfection tank,
An inlet unit to which the treated water transferred from the second settling tank is introduced;
An outlet for discharging the treated water transferred from the second settling tank to the outside; And
And a plurality of partition walls for forming a flow path through which the treated water transferred from the second settling tank moves from the inlet to the outlet.
Each partition is composed of a plurality of ultrasonic generators that can be assembled,
The ultrasonic wave generator is configured in a rectangular shape,
On the remaining four surfaces except the upper surface and the lower surface, each of the ultrasonic generator and the switch unit for operating the ultrasonic generator provided on the four surfaces, respectively
The ultrasonic generator,
When the first surface of the four surfaces are assembled so as to be adjacently coupled with the other ultrasonic generator, by the assembly, the switch unit provided on the first surface is controlled so that the ultrasonic generator provided on the first surface does not operate. Processing system. The method of claim 1,
The plurality of partitions may include a plurality of barrier ribs,
Waste water treatment system characterized in that the one side and the other side is configured to alternately open for each partition in the disinfection tank so that the flow path is formed in a zigzag. delete delete delete In the ultrasonic generator for removing bacteria from the waste water,
Fastening parts provided on each of the remaining four surfaces except for the top and bottom surfaces so as to be assembled with other ultrasonic generators;
Ultrasonic generators provided on the four surfaces; And
Switches provided on the four surfaces such that the ultrasonic generator does not operate when the other ultrasonic generator is assembled on the fastening unit, and the ultrasonic generator operates when the other ultrasonic generator is not assembled on the fastening unit. Ultrasonic generator comprising a. delete

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