KR102097471B1 - Wastewater nitrogen treatment system using denitrification tower - Google Patents

Abstract

The present invention is a raw water storage tank in which raw water including waste water is stored; One or more denitrification towers for discharging the treated water from which the nitrogen nitrate is removed from the raw water by supplying raw water from the raw water storage tank and filling a plurality of media therein; A treated water storage tank for receiving and storing treated water from the denitrification tower; It relates to a waste water nitrogen treatment system using a denitrification tower, characterized in that it comprises; a backwash water storage tank for supplying the backwash water to the denitrification tower.

Description

Wastewater nitrogen treatment system using denitrification tower

The present invention relates to a wastewater treatment system using a denitrification tower to improve the denitrification efficiency.

2. Description of the Related Art In general, physical and biological methods are used in parallel to treat contaminants, organic substances, nitrogen, and phosphorus present in sewage and wastewater. In particular, nitrogen present in sewage and wastewater is treated by nitrifying organic nitrogen or ammonia nitrogen by biological methods and then reducing it with nitrogen gas by installing a reaction tank that performs nitrification reaction and a denitrification reaction in the wastewater and wastewater treatment system. Doing.

Such biological nitrification / denitrification is usefully applied to treatment of sewage and wastewater containing high concentrations of organic substances such as leachate and livestock wastewater and ammonia nitrogen. At this time, it is more efficient when the C / N (organic / nitrogen) values of the inflow and waste water are large. In order to use the organic material in raw water as an electron donor, in this nitrification / denitrification process, a system operated in the order of denitrification / post nitrification using effluent transport or internal transport in consideration of C / N ratio in sewage and waste water is mainly used. .

Republic of Korea Registered Patent No. 566053

The present invention is to provide a system for doubling the biological treatment efficiency of nitrogen mixed in waste water, as described above.

In order to achieve the above object, the wastewater nitrogen treatment system using the denitrification tower according to the present invention (hereinafter referred to as "the system of the present invention") is provided with a heating means, and raw water containing wastewater is stored. Storage tank; The raw water is introduced from the raw water storage tank, and a plurality of media is filled therein to denitrify the nitric acid nitrogen mixed into the raw water by forming a colony of denitrifying bacteria to remove nitric nitrate from the raw water and discharge the treated water. At the top, one or more denitrification towers are formed with a nitrogen discharge line to discharge the collected nitrogen; A treated water storage tank for receiving and storing treated water from the denitrification tower; A backwash water storage tank supplying backwash water to the denitrification tower; And a methanol storage tank for supplying methanol to the denitrification tower, wherein the denitrification tower is composed of two or more, so that the denitrification towers are connected in series or in parallel. The stirrer is composed of a plurality of stirring blades that protrude from the rotating shaft in plural to form a rotating water flow so that the media forms a fluidized bed by rotating water from the raw water, wherein the water level can be determined in the denitrification tower in the rotating shaft. The slide teeth are configured in the upper and lower directions on the part, and the second slide teeth are installed inside the slide portion and the slide portion, which are composed of the control jaws at the upper and lower ends, and are made of a floating material and engaged with the slide teeth. It is composed and rotates like a rotating shaft while interlocking up and down in the slide part according to the water level. A bubble removal tool consisting of a foam and a foam removal blade that protrudes in a plurality from the clamp and the clamp and is made of a floating material and flows along the water level in the up and down direction and interlocks with the rotation of the rotating shaft to push the foam outward from the water level. Characterized in that it further comprises.

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As described above, the present invention has the advantage of increasing the biological treatment efficiency of nitrogen mixed in sewage and waste water.

In addition, the present invention has the advantage of being able to utilize the treated water as backwashing water and to continuously operate even when backwashing when the denitrification tower is composed of a plurality.

1 is a block diagram showing the system of the present invention,
Figure 2 is a schematic operating state diagram of a denitrification tower which is one configuration of the present invention,
Figure 3 is a working state diagram of another embodiment in the denitrification tower which is one configuration of the present invention.

Hereinafter, a preferred embodiment according to the present invention will be described in detail.

The system 1 of the present invention includes a raw water storage tank 2 in which raw water including waste water and waste water is stored, as shown in FIG. 1; One or more denitrification towers (3) for discharging treated water from which raw water is introduced from the raw water storage tank (2) and a plurality of media is filled therein to remove nitrogen nitrate from the raw water; A treatment water storage tank 4 for receiving and storing treated water from the denitrification tower 3; And a backwash water storage tank (5) for supplying backwash water to the denitrification tower (3).

The raw water storage tank 2 is a structure for storing waste water and waste water discharged from various facilities. The raw water storage tank 2 is not shown in the drawings, but is equipped with a heating means. In particular, in the winter, organic substances included in the waste water When the nitrification of sonar ammonia nitrogen is not smoothly performed, the raw water stored in the raw water storage tank 2 may be heated to allow the nitrification of organic nitrogen and ammonia nitrogen contained in the raw water to be smooth. That is, the denitrification reaction is smoothly performed in the denitrification tower 3 in the rear stage to increase nitrogen removal efficiency from raw water.

The denitrification tower 3 corresponds to a configuration in which raw water stored in the raw water storage tank 2 is introduced to reduce nitrogen nitrate mixed into the raw water to nitrogen by denitrifying bacteria to discharge the treated water from which nitrogen has been removed.

The denitrification tower 3 is configured in a closed shape so that raw water is introduced from the raw water storage tank 2 at one side and treated water is discharged at the other side. Although a drawing number is not shown at the top, a nitrogen discharge line is formed. By doing so, the nitrogen trapped at the upper end of the denitrification tower 3 is discharged.

The denitrification column 3 is filled with a plurality of media 32, so that the denitrification reaction of nitrogen nitrate mixed with raw water is performed by colonization of denitrifying bacteria in the media 32.

Denitrification by these denitrification bacteria can be said to be very efficient in terms of removing nitric acid nitrogen when using an appropriate amount of organic matter, and thus a methanol storage tank 6 for supplying methanol to the denitrification tower 3 is further shown in FIG. Should be configured.

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The denitrification tower 3 is not shown in the drawings in the system 1 of the present invention, but is composed of a plurality of denitrification towers 3 to enable serial or parallel connection. If you want to take a large processing capacity, you can connect the denitrification towers (3) in series and use them. In order to enable continuous operation even in backwashing, you can connect the denitrification towers (3) in parallel. have. In addition, the series or parallel connection between the denitrification towers 3 may be selectively made.

In addition, as shown in FIG. 2, the denitrification tower 3 is configured with a stirrer 33, and the stirrer 33 is connected to a rotation shaft 331 and the rotation shaft 311 interlocking with a motor (m). It is composed of a plurality of stirring blades 332 to protrude in plural to form a rotating water stream so that the media 32 forms a fluidized bed by rotating water from raw water.

As mentioned above, by the action of the stirrer 33, the media 32 is formed so that a fluidized bed is formed by rotational flow from raw water so that the denitrification reaction is uniformly and efficiently performed. However, the foam layer is formed on the surface of the water by the action of the stirrer 33. The foam layer is a nitrogen gas generated as a result of the denitrification reaction, which is a trapped space formed at the upper end of the denitrification tower 3, and prevents the flow. In this case, nitrogen is re-mixed and acts as a factor to reduce denitrification efficiency.

Accordingly, in the present invention, as shown in FIG. 3, a slide portion 333 in which the slide teeth are configured in the up and down direction is configured in the portion where the water level can be determined in the denitration tower 3 in the rotating shaft 331, It is mounted on the slide portion 333, is made of a floating material, and a plurality of clamps 341 and clamps 341 protruding from the clamp 341 are configured to be engaged with the slide teeth. It presents an example in which the defoaming port 34 composed of the defoaming blades 342 for removing bubbles from the water level is further configured.

As shown in FIG. 3, the slide part 333 is configured as an upper part of the rotating shaft 331 and is formed on an upper part of the uppermost stirring blade 332, but is formed in a portion where the water level can be determined in the denitrification tower 3. . The slide portion 333 is composed of a slide tooth in the up and down direction, which is the bubble removal port 34 mounted on the slide portion 333 while flowing along the water level in the up and down direction of the rotating shaft 331 It is intended to enable rotational interlocking of the defoaming opening (34) in conjunction with rotation.

Although the drawing numbers are not shown at the upper and lower ends of the slide part 333, a control jaw is formed to control the up and down linkage of the bubble removal port 34 that slides up and down in the slide part 333. shall.

The defoaming port 34 is not limited to the material, but is made of a floating material and is interlocked with the water level fluctuation in the denitrification tower 3 so that the defoaming port 34 is located on the fluctuating water surface.

The clamp 341 is configured to be mounted on the slide portion 333, and a second slide tooth is configured therein to engage with the slide tooth, and the rotating shaft while interlocking up and down in the slide portion 333 according to the water level. It corresponds to the configuration to rotate as shown in (331).

The defoaming wing 342 blows the foam formed on the surface of the water or pushes the foam outward so that nitrogen gas can be discharged out of the water surface.

As mentioned above, the treated water from which nitrogen is removed from the denitrification tower 3 is introduced into the treated water storage tank 4, and the treated water storage tank 4 discharges the stored treated water into a discharge or post-treatment process. It is possible.

In addition, a backwash water storage tank (5) is configured to supply backwash water to the denitrification tower (3) so that the denitration tower (3) is backwashed, so that the treated water from the denitration tower (3) is supplied to the treated water storage tank (4). It is connected to the supply line by a valve so that the treated water is stored in the backwash water storage tank (5). That is, it is possible to recycle the treated water of the denitrification tower 3 to the backwashed water without supplying backwashed water from the outside.

As described above, although the present invention has been described with limited embodiments and drawings, the present invention is not limited to the above embodiments, and the contents described above by those skilled in the art to which the present invention pertains Of course, various modifications and variations may be possible.

1: System of the present invention 2: Raw water storage tank
3: Denitrification tower 4: Treated water storage tank
5: backwash water storage tank

Claims (5)

A raw water storage tank in which a heating means is provided and raw water including waste water is stored;
The raw water is introduced from the raw water storage tank, and a plurality of media is filled therein to denitrify the nitrogen nitrate mixed into the raw water by forming a colony of denitrifying bacteria to remove nitric nitrate from the raw water and discharge the treated water. At the top, one or more denitrification towers are formed with a nitrogen discharge line to discharge the collected nitrogen;
A treated water storage tank for receiving and storing treated water from the denitrification tower;
A backwash water storage tank supplying backwash water to the denitrification tower; And
It includes; a methanol storage tank for supplying methanol to the denitrification tower,
The denitrification tower is composed of two or more, and the denitrification towers are connected in series or parallel.
In the denitrification tower, a stirrer composed of a rotating shaft interlocked with a motor and a plurality of stirring blades protruding from the rotating shaft to form a rotating water stream so that a media forms a fluidized bed by rotating water from raw water is formed. It works,
In the rotating shaft, in the denitrification tower, the slide teeth are configured in the upper and lower directions in the portion where the water level can be determined, and the upper and lower ends are mounted on the slide portion and the slide portion, respectively. A second slide tooth is configured inside to engage with the slide tooth, and the clamp rotates like a rotating shaft while interlocking up and down in the slide part according to the water level, and a plurality of protrusions protruding from the clamp and made of a floating material, Lower and waste water nitrogen treatment using a denitrification tower further comprising a defoaming blade composed of a defoaming blade that moves along the water level in the downward direction and interlocks with the rotation of the rotating shaft to push bubbles outward from the water level. system. delete delete delete delete

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