KR102026130B1 - Wastewater treatment apparatus for ships - Google Patents

Abstract

The present invention relates to a wastewater treatment apparatus for a ship, capable of preventing marine pollution. According to the present invention, the wastewater treatment apparatus for a ship comprises: a floating matter removing tank; a first precipitation tank connected to the floating matter moving tank; an anaerobic tank connected to the first precipitation tank and removing phosphorous and nitrogen included in wastewater; a non-oxygen tank connected to the anaerobic tank; an aeration tank having a plurality of aeration plates formed on a bottom surface to eject air and to which a moving bed bioreactor (MBBR) is inputted; a mixing module sucking the wastewater and the MBBR from an inlet and discharging the same to an ejection hole; a second precipitation tank installed to be connected to the aeration tank; and an outlet connected to a discharge unit, the floating matter removing tank, the first precipitation tank, and the anaerobic tank, and the second precipitation tank, and discharging sludge included in the wastewater therefrom.

Description

Wastewater treatment apparatus for ships

The present invention relates to a marine wastewater treatment apparatus, and more particularly, to a marine wastewater treatment apparatus capable of preventing marine pollution by treating various wastewaters generated from a vessel.

Conventionally, various raw water treatment systems have been developed. These treatments are usually designed to have multiple stages of filtration, including successive treatment stages of coagulation, precipitation and sedimentation.

Raw water to be treated includes surface water, surface water, sewage, brine, seawater and others. One of the conventional raw water treatment methods is based on an activated sludge process (ASP). It is filtered to remove sludge-containing inclusions, suspended solids, etc., to remove solids and to pre-treat raw water. Thereafter, an aeration section or aeration tank is provided for injecting air into the tank so that air is supplied to the treated raw water.

Other raw water treatment systems include the use of membrane bioreactors (MBRs). The system is similar to the system described above for the initial stages of flotation and pretreatment, and for providing raw water to the aeration or aeration tank, but the MBR treatment is replaced by the sedimentation tank and additional filtration or sterilization treatment. MBR treatment employs a special membrane used to treat raw water with a total suspended solids (TSS) of 5-12000 mg / l.

MBR treatment uses ultra-filtration (UF) membranes and microfiltration (MF) membranes. The pore size of the membrane ranges from 0003 to 001 μm. MBR treatment usually submerges the membrane in a Bio Reactor. The immersed shape depends on the bubble aeration device for the production of the mixture and for limiting membrane fouling. The aeration keeps the solids suspended and cleans the membrane surface. In addition, oxygen is supplied to microorganisms to induce better decomposition and cell synthesis.

MBR filtration performance decreases over time due to the deposition of soluble particulate matter on the surface and inside of the membrane. Membrane membrane contamination is the result of the interaction between the membrane material and the activated sludge component. This includes, but is not limited to, biological flocs formed by living or dead microorganisms in the form of solubility and colloidal state compounds. Membrane membrane contamination is a serious problem that affects system performance.

This is because it greatly increases the hydraulic resistance and reduces the melt flow or increases the Trans-Membrane pressure (TMP). Therefore, periodic cleaning and replacement of the membrane is required.

Another raw water treatment technique is known as a moving bed bioreactor (MBBR). MBBR technology employs an improved and capacity wastewater treatment process that utilizes floating biofilm conveying elements of aerobic and anaerobic reactors and anaerobic reactors. The conveying element is actually a mixture between the deposit and the growth treatment process of the float and requires less space and natural resources for installation and operation than other treatment methods.

Biofilm conveying elements provide a very large effective biofilm surface area. The biomass is held inside the conveying element, which is held inside the reactor by the sieve of the outlet. This carrier element is moved by a rotary air blower in an aerobic system and a bubble air distribution system by a mixer of anoxic and anaerobic systems. When using the MBBR technique, the charge proportion of the carrier in the reactor can be changed in response to the specific load of the raw water. Treatment plants can also be designed by the combination process for the composition and target specific contaminants of multiple MBBRs.

MBBR method, which is one of the methods for raw water treatment, is known to be more effective than other treatment methods, but more environmentally friendly and efficient MBBR technology is required.

Conventionally, the raw water is treated by adopting the MBBR method, but the floating water or sediment contained in the raw water is included in the aeration tank, thereby reducing the raw water treatment efficiency, thereby requiring a lot of raw water treatment cost and time.

Korean Patent Publication No. 10-2012-0069587 "Membrane Bioreactor Raw Water Treatment System and Mobile Phase Bioreactor Raw Water Treatment System" (Publishing Date: 2012.06.28)

The present invention has been made in order to solve the above problems, the primary filtering of the suspended solids and sediments contained in the incoming raw water, improve the raw water treatment efficiency by treating the raw water does not contain the impurities in the form of particles in the MBBR method Its main purpose is to provide environmentally friendly marine wastewater treatment equipment.

Wastewater treatment apparatus for ships according to the present invention is a wastewater flow in, the float removal tank for removing the suspended matter contained in the introduced wastewater, a first precipitation tank connected to the float removal tank, and connected to the first precipitation tank, included in the wastewater Anaerobic tank for removing the phosphorus and nitrogen, an anaerobic tank connected to the anaerobic tank, and connected to the anaerobic tank, MBBR (Moving Bed Bioreactor, mobile phase bioreactor) is introduced, the bottom surface is a plurality of aeration plate to eject air A mixing tank to be formed, installed inside the aeration tank, an inlet is formed in the lower portion, and a spout is formed in the upper portion of the mixing module for sucking the wastewater and MBBR from the inlet and then discharging it to the spout; It is connected to the second sedimentation tank and the upper side of the second sedimentation tank is installed, the treated water is discharged from the waste water Ryubu and the suspension removal tank and the first precipitation tank, anaerobic tank, and are respectively connected to a second settling tank, characterized in that it comprises an outlet in which the sludge included in waste water discharge.

In addition, the discharge side of the aeration tank is provided with a screen net is characterized in that to filter out the foreign matter.

In addition, it is characterized in that it comprises a secondary sedimentation tank to receive the sludge discharged in connection with the lower portion of the second sedimentation tank.

In addition, the mixing module is a housing in which the submersible pump is built, the housing is connected to the upper portion, the flow pipe bent in the 'c' shape, and the auxiliary air pipe connected to the lower side of the flow pipe to supply air into the flow pipe Characterized in that it comprises a.

In addition, the aeration plate is formed with a plurality of aeration hole, the aeration control port is provided on the upper side of the aeration plate is provided, the aeration control port is a position corresponding to the aeration hole in the aeration control frame and the bottom of the aeration control frame Characterized in that consisting of the pin is provided as.

The marine wastewater treatment apparatus according to the present invention removes impurities in the form of particles floating in the wastewater by introducing the wastewater to treat various wastewaters (hereinafter, wastewater) generated according to the operation of the vessel, and the precipitated impurities are Since it is removed and moved in the first settling tank, the liquid wastewater is treated in the aeration tank to provide an effect of improving treatment efficiency.

In addition, while mixing the wastewater and MBBR more actively by the mixing module installed inside the aeration tank, through the additional air supply to provide an effect that can be made more wastewater treatment.

1 is a schematic configuration diagram showing a marine wastewater treatment apparatus according to an embodiment of the present invention.
Figure 2 is an exemplary view showing an aeration plate and aeration control device of the present invention.
3 is an exemplary view showing a mixing module of the present invention.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings.

The accompanying drawings are only examples to illustrate the technical idea of the present invention in more detail, and thus the technical idea of the present invention is not limited to the forms of the accompanying drawings.

However, in the following description of the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

1 is a schematic configuration diagram showing a marine wastewater treatment apparatus according to an embodiment of the present invention.

As shown in FIG. 1, the marine wastewater treatment apparatus 1000 of the present invention includes a float removing tank 100, a first precipitation tank 200, an anaerobic tank 300, an anaerobic tank 400, an aeration tank 500, and a mixing module. 600, a second settling tank 700, a discharge part 800, an outlet 900, and an auxiliary settling tank 950.

First, the float removal tank 100 is a variety of wastewater generated in accordance with the operation of the vessel is introduced, it is configured to remove the float contained in the introduced wastewater.

At this time, in the float removal tank 100, the outlet 900 is connected to the surface of the waste water so that impurities floating in the waste water are removed, and is connected to the first precipitation tank 200 at the lower side of the float removal tank 100. The first connecting pipe 101 is formed.

Next, the first sedimentation tank 200 is connected to the float removal tank 100, the first connecting pipe 101 is connected to the upper side of the first sedimentation tank 200 waste water that is moved from the first sedimentation tank 200 Falls to the first settling tank 200.

The first settling tank 200 is configured to remove impurities precipitated in the wastewater in the state in which the floating impurities contained in the wastewater are removed from the float removing tank 100, and an outlet 900 is connected to the lower side, and an anaerobic tank ( The second connecting pipe 201 connected to the 300 is connected to the upper side.

The anaerobic tank 300 is connected through the first settling tank 200 and the second connection pipe 201, and removes phosphorus and nitrogen contained in the wastewater from which the particulate impurities moved from the first settling tank 200 are removed. , The anaerobic tank 400 is connected to the anaerobic tank 300 to further remove phosphorus and nitrogen contained in the waste water.

Next, the aeration tank 500 is connected to the oxygen-free tank 400, the MBBR (Moving Bed Biofilm Reactor) is introduced into the inside, the bottom surface is formed with a plurality of aeration plate 31 for blowing air.

MBBR is a technology developed by competing with the conventional activated sludge process and biofilm process only. It has a high surface area and easy structure for microbial adhesion and air permeation, and has good fluidity and guarantees excellent efficiency in treating organic matter, nitrogen, and phosphorus. .

In detail, as shown in FIG. 2, the bottom surface of the aeration tank 500 is formed with an aeration plate 510 through which the air forcedly supplied from the outside is formed, and the aeration plate 510 has a plurality of aerations. Holes 511 are formed to allow air to be uniformly supplied and blown out.

Preferably, the air that is ejected while being raised through the aeration plate 510 of the aeration tank 500 needs to be ejected in a more various pattern. If the air blowing pattern is constantly constant, it may be necessary to change the air blowing pattern intermittently because a stagnant area may be generated in a specific area.

In the present invention, the aeration control port 520 that is movable above the aeration plate 510 is disposed.

The aeration regulator 520 is a pin of a pin shape formed at a position corresponding to the aeration hole 511 formed in the aeration plate 510, a plurality of pins 522 is formed in the lower portion of the aeration control frame 521 As the opening degree of the aeration hole 511 is changed by adjusting the up and down positions of the aeration control port 520, the aeration pattern may be more variously implemented.

Usually, the aeration regulator 520 is raised as much as possible so that the pin 522 does not block the aeration hole 511 and sets a predetermined time interval so that the aeration regulator 520 is lowered so that the pin 522 is aeration hole ( If you partially block 511, the aeration pattern will be different, depending on the degree of falling of the aeration control 520 can implement a variety of patterns.

More preferably, the pin 522 of the aeration control 520 is basically in the form of a pinch, by combining a plurality of pins 522 of different sizes to configure the aeration control 520.

That is, when a plurality of pins 522 having different lengths or outer diameter sizes of the pins 522 are used in combination, more various aeration patterns may be formed according to the height adjustment of the aeration regulator 520.

Next, the mixing module 600 is provided inside the aeration tank 500, an inlet 631 is formed at the lower portion, and a dividing hole 632 is formed at the upper portion, and the wastewater and MBBR accommodated in the aeration tank 500. Sucked from the inlet 631 and discharged to the spout 632 to stir the waste water and MBBR in the aeration tank 500.

In detail, as shown in FIG. 3, the mixing module 600 includes a submersible pump 610, a housing 620, a flow pipe 630, and an auxiliary air pipe 640.

The submersible pump 610 is built in the housing 620, the housing 620 is installed adjacent to the bottom surface of the aeration tank 500, the submersible pump 620 is installed inside the housing 620, the housing ( A plurality of wastewater inlets 621 are formed at 620.

The flow pipe 630 is connected to the upper portion of the housing 620, the flow pipe 630 is made of a pipe bent in a substantially '' 'shape. The lower end of the flow tube 630 is connected to the upper portion of the housing 620, and the lower end of the flow tube 630 becomes the inlet 631. The flow pipe 630 is bent in a 'c' shape to be made of a rising section, a horizontal section, a falling section, the end of the falling section is a spout 632.

On the other hand, in order to be able to supply air into the flow pipe 630, the auxiliary air pipe 640 is connected to the lower side of the flow pipe 630.

Basically, the mixing module 600 raises the waste water of the aeration tank 500 through the flow pipe 630 by the pumping action of the submersible pump 610 to discharge at a position higher than the water surface. MBBR also moves along the flow pipe 630 along the flow generated by the submersible pump 610, and at the same time, the air is forcedly supplied through the auxiliary air pipe 640, so that the decomposition of the waste water can be efficiently performed through a smooth and sufficient air supply. Can be done.

Subsequently, the second precipitation tank 700 is installed next to the aeration tank 500. The waste water moved to the second precipitation tank 700 has already been purified to some extent in the aeration tank 500, and is formed as sludge by allowing fine foreign matter to precipitate while remaining in the second precipitation tank 700. In the second sedimentation tank 700, the fine foreign matter is accumulated on the bottom of the sedimentation tank in the form of sludge, the outlet port 900 is connected to the lower portion of the second sedimentation tank 700 and the sludge is discharged through the outlet 900.

And the discharge water 800 is connected to the upper side of the second settling tank 700, the filtered water treated in the second settling tank 700 is discharged.

On the other hand, the secondary sedimentation tank 700 may be further provided with an auxiliary sedimentation tank, and serves to receive the sludge accumulated in the second sedimentation tank 700 to perform secondary treatment.

Wastewater is still included in the sludge transferred to the auxiliary sedimentation tank, and even when the treatment capacity of the second sedimentation tank 700 is insufficient, the sludge and the wastewater are transferred together to the auxiliary sedimentation tank to generate sludge. Capacity can be increased.

In addition, the discharge part 800 is connected to the auxiliary sedimentation tank, and the sludge and waste water transferred to the auxiliary sedimentation tank are once again treated with sedimentation, thereby allowing the discharge of more completely treated filtrate.

The discharge unit 800 may be connected to the discharged filtered water for further treatment or intended end use to discharge the filtered water.

The present invention is not limited to the above-described embodiments, and the scope of application is not limited, and various modifications can be made without departing from the gist of the present invention as claimed in the claims.

1000: Marine Wastewater Treatment System
100: float removal tank 101: first connector
200: first settling tank 201: second connecting pipe
300: anaerobic tank 400: anaerobic tank
500: aeration tank 510: aeration board
511: aeration hole 520: aeration control
521: aeration control frame 522: pin
600: mixing module 610: submersible pump
620: housing 621: waste water inlet
630: flow pipe 631: inlet
632: outlet 640: auxiliary air
700: second settling tank 800: discharge portion
900 outlet

Claims (5)

Waste water is introduced, the float removal tank for removing the suspended matter contained in the introduced waste water;
A first settling tank connected to the float removing tank;
An anaerobic tank connected to the first precipitation tank to remove phosphorus and nitrogen contained in the wastewater;
An anaerobic tank connected to the anaerobic tank;
An aeration tank connected to the anoxic tank, in which a moving bed bioreactor (MBBR) is input, and a plurality of aeration plates to which air is ejected are formed on the bottom surface;
A mixing module installed inside the aeration tank, a inlet is formed in the lower portion, and a spout is formed in the upper portion to suck the wastewater and MBBR from the inlet and discharge the spout into the spout;
A second settling tank installed to be connected to the aeration tank; And
A discharge part connected to an upper side of the second settling tank and discharging the filtered water treated in the second settling tank;
And a discharge port connected to each of the suspended matter removing tank, the first settling tank, the anaerobic tank, and the second settling tank, each of which is provided with an opening and closing means and discharges sludge contained in the wastewater.
The discharge side of the aeration tank is provided with a screen net to filter foreign matter, and is further provided with an auxiliary sedimentation tank to receive the sludge discharged in connection with the lower portion of the second sedimentation tank,
The mixing module,
It includes a housing in which the water pump is built, connected to the upper housing, the flow pipe bent in the 'c' shape, and an auxiliary air pipe connected to the lower side of the flow pipe to supply air into the flow pipe,
The aeration board,
A plurality of aeration holes are formed, the aeration control port is provided to move up and down in the upper side of the aeration plate, the aeration control port is made of aeration control frame and a pin provided at a position corresponding to the aeration hole on the bottom of the aeration control frame. Wastewater treatment apparatus for ships, characterized in that. delete delete delete delete

Images