KR102202456B1 - Biologic advanced water treatment system by utilizing pressure tank - Google Patents

Abstract

The present invention provides a biological advanced water treatment system using a pressure tank. Such an advanced biological water treatment system using a pressure tank according to the present invention has a luxury uptake of phosphorus even at a minimized system scale in which an aerobic tank, blower, and air diffusers provided as essential components of a conventional advanced biological water treatment facility are removed. A tank with a reduced internal space through a pressurized exhalation tank with a structure that can perform nitrification with high treatment efficiency, and can increase the efficiency of oxidation and decomposition of contaminated water, activity of microorganisms, and oxidation-nitrification of organic matter. ) Can be used, while a system without internal transfer can be implemented, thereby reducing energy savings, installation and maintenance costs, thereby improving economics and efficiency.

Description

Biologic advanced water treatment system by utilizing pressure tank

The present invention relates to an advanced biological water treatment system using a pressure tank, and more specifically, an excessive intake of phosphorus even at a minimized system scale in which an aerobic tank, a blower, and a diffuser provided as essential components of a conventional advanced biological water treatment facility are removed ( Luxury uptake and nitrification can be performed with high treatment efficiency, and the internal space size is reduced through a pressurized exhalation tank with a structure that can increase the efficiency of oxidation and decomposition of contaminated water, the activity of microorganisms, and the oxidation-nitrification of organic matter. A biological advanced water treatment system using a pressure tank that improves economy and efficiency by saving energy, reducing installation and maintenance costs by enabling the use of a tank that has been used while a system without internal transfer can be implemented. It is about.

Technology for treating contaminated water such as contaminated water is currently widely distributed and used. In the case of a biological water treatment system using microorganisms, Korean Patent Publication No. 10-0473639 "Advanced sewage using organic acids produced from sewage sludge Technologies such as treatment system and advanced sewage treatment method", Patent Application Publication No. 10-2014-0130821 "Sewage treatment device in which the internal and external transport of sludge proceeds through an integrated pipeline, and a sewage treatment method using the same" Are developed and used.

However, most of the biologically advanced water treatment facilities that have been put into practical use up to now have a high energy consumption and a situation in which contaminated water is treated using blowers, air diffusers, and internal conveyance, which require a lot of facility cost. In particular, in a biologically advanced water treatment facility to remove nitrogen and phosphorus, tanks that are essentially used such as anaerobic tanks, anoxic tanks, aerobic tanks, and sedimentation tanks were required.In the aerobic tank, air (oxygen) was supplied to the maximum to provide nitrification and excessive phosphorus intake Luxury uptake) was performed to treat nitrogen and phosphorus by receiving a carbon source from the anaerobic and anoxic tanks.

Korean Registered Patent Publication No. 10-0473639 "Advanced sewage treatment system and advanced sewage treatment method using organic acids produced from sewage sludge" Korean Patent Laid-Open Publication No. 10-2014-0130821 "Sewage treatment apparatus in which internal and external transport of sludge proceeds by an integrated pipeline, and a sewage treatment method using the same"

Accordingly, the present invention improves the problems of the prior art, and the internal space size is reduced through a tank having a structure that can increase the efficiency of oxidation and decomposition of contaminated water, the activity of microorganisms, and the oxidation-nitrification efficiency of organic matter. ) Can be used, while the aerobic tank, blower, and air diffusers, which are equipped as essential components of the conventional high-level biological water treatment facility, are removed and internal conveyance is omitted, even in a minimal system scale, luxury uptake and nitrification ( The purpose of this study is to provide an advanced biological water treatment system using a new type of pressure tank that can perform nitrification) with high treatment efficiency.

Accordingly, an object of the present invention is to provide a biologically advanced water treatment system using a new type of pressure tank that can improve economy and efficiency by reducing energy consumption, installation and maintenance costs.

According to a feature of the present invention for achieving the above object, the present invention is a first flow tank 10 into which a part of raw water consisting of contaminated water is introduced; A second flow tank 20 into which the rest of the raw water made of contaminated water flows; It is connected to the second flow tank 20 and the second pipe 130, and the raw water of the second flow tank 20 injected by pumping is pressurized to maintain an internal pressure of 2 to 7 kg/cm ² The raw water with increased dissolution rate is accommodated, microorganisms are accommodated therein, and the raw water is oxidized and decomposed by adsorption of the microorganisms and raw water to generate treated water with luxury uptake and nitrification of phosphorus. A pressurized exhalation tank 30; It is connected to the pressurized exhalation tank 30 and the third pipe 140, while being connected to the first pipe 120 of the first flow tank 10, the treated water of the pressurized exhalation tank 30 and the first The raw water of the flow tank 10 is supplied and stored in a mixture, and the raw water of the first flow tank 10 is used as a carbon source for the first denitrification of the treated water of the pressurized exhalation tank 30. ) Proceeds, and in the mixing process between the treated water of the pressurized exhalation tank 30 and the raw water of the first flow tank 10, some bubbles in the treated water are removed while the remaining bubbles in the treated water are dispersed into the atmosphere. , An aerobic storage tank 40 for preventing the loss of sludge by attaching a portion of the sludge contained in the treated water to the inner space; It is connected to the expiratory storage tank 40 and the fourth pipe 150 so that the treated water of the expiratory storage tank 40 is input and divided into a first area 54, a second area 55, and a third area 56. As the second denitrification and sludge sedimentation proceeds, the anaerobic tank and the anoxic tank are performed, and are treated with the first flow tank 10 and the second flow tank 20 through the seventh pipe 180 A complex treatment tank (50) that allows water to be returned to realize anaerobic conditions for excessive phosphorus intake; It is installed in the second pipe 130 and pumps raw water from the second flow tank 20 and puts it into the pressurized exhalation tank 30 in a pressurized state, so that the pressurized exhalation tank 30 is transferred to a high pressure pump 80 ); Includes; an ejector 90 installed in the second pipe 130, disposed behind the high pressure pump 80, and mixing air introduced from the outside with raw water and introducing it into the pressurized exhalation tank 30; Consists of
The first area 54 of the complex treatment tank 50 forms an upper part, and the treated water is supplied to the inner cylinder 58 from the expiratory storage tank 40 and the fourth pipe 150 to be a non-pressure flow. It is moved from the inner cylinder 58, and the discharge port 53 is formed at the set height to be the area where the treated water is discharged, and the second area 55 of the complex treatment tank 50 forms a middle part and is formed as an oxygen-free area. It is an area in which a mixer 51 connected to the motor 52 is arranged vertically to induce denitrification through mixing of treated water, and the third area 56 of the complex treatment tank 50 is a lower part Is a region where sludge is precipitated and accumulated, and the external thickening tank 60 is connected through the sixth pipe 170,
Treatment of the pressurized exhalation tank 30 through the third pipe 140 in which one end is connected to the upper portion of the pressurized exhalation tank 30 and the other end is horizontally disposed under the exhalation storage tank 40 Water is introduced into the exhalation tank 40 by the pumping operation of the high pressure pump 80 and the internal pressure of the pressurized exhalation tank 30, and the third pipe 140 is the lower edge of the exhalation storage tank 40. It is arranged in a shape that is wound toward the center from the side and gradually decreases in size toward the center to prevent the occurrence of dead space in the lower portion of the expiratory storage tank 40. It provides a biological advanced water treatment system using a pressure tank.

In such an advanced biological water treatment system using a pressure tank according to the present invention, the pressurized exhalation tank 30 includes a plurality of partition wall layers 32 formed by one or more partition walls 31 that are horizontally spaced apart in the vertical direction. It is configured, but a large amount of microorganisms are attached to the sponge filter material layer 33 disposed on each partition layer 32, so that the luxury uptake and nitrification efficiency of phosphorus to the raw water can be increased.

In such an advanced biological water treatment system using a pressure tank according to the present invention, the aerobic storage tank 40 is disposed on an upper portion and attaches a portion of the sludge contained in the treated water to prevent the loss of sludge while the pressurized exhalation tank ( It may include a piece sponge network 41 to remove the air bubbles dissolved in 30).

According to the biologically advanced water treatment system using a pressure tank according to the present invention, the luxury uptake and nitrification of phosphorus are performed with high treatment efficiency even at a minimized system scale in which an aerobic tank, a blower, and a diffuser are removed. have. Here, as the aerobic tank, blower, and diffuser are removed, the cumbersome procedure for replacing the diffuser becomes unnecessary, unlike the conventional system in which the treated water in the water tank must be completely or partially discharged to replace the consumable diffuser. It also has the effect of reducing the cost associated with it.

And according to the biological advanced water treatment system using the pressure tank according to the present invention, the internal space of the pressurized exhalation tank having a structure in which the efficiency of oxidation and decomposition of contaminated water, the activity of microorganisms, and the efficiency of oxidation-nitrification of organic matter is increased, replacing the conventional aerobic tank. A tank with a reduced size is used, and a large amount of air is simultaneously supplied with raw water to induce nitrification of organic substances, nitrification, and excessive intake of phosphorus in a short time. In addition, as a system in which internal transport and inflow of carbon sources from the outside are omitted is implemented, energy savings, installation and maintenance costs can be reduced, thereby improving economy and efficiency.

1 is a view for showing the configuration of a biological advanced water treatment system using a pressure tank according to an embodiment of the present invention;
Figure 2 is a view for showing the internal configuration of the pressurized exhalation tank according to an embodiment of the present invention;
3 is a view for showing the internal configuration of an expiratory storage tank according to an embodiment of the present invention;
4 is a view for showing the arrangement structure of the third pipe in the lower portion of the expiratory storage tank according to an embodiment of the present invention;
5 is a diagram showing the configuration of a complex treatment tank according to an embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 5 of the accompanying drawings. On the other hand, in the drawings and detailed description, the general contaminated water advanced water treatment system, flow tank, expiratory storage tank, thickening tank, pump, ejector, luxury uptake of phosphorus, nitrification, denitrification, etc. The illustrations and references to the configuration and operation that can be easily understood have been simplified or omitted. In particular, in the illustration and detailed description of the drawings, detailed descriptions and illustrations of specific technical configurations and actions of elements not directly related to the technical features of the present invention are omitted, and only the technical configurations related to the present invention are briefly illustrated or described. I did.

The biological advanced water treatment system 1 using a pressure tank according to an embodiment of the present invention includes a first flow tank 10, a second flow tank 20, a pressurized exhalation tank 30, an expiratory storage tank ( 40), consists of a configuration including a complex treatment tank (50).

The first flow tank 10 is a device through which a part of raw water consisting of contaminated water is introduced, and accommodates 10 to 40% of the total flow of raw water. In addition, the first flow tank 10 supplies 10 to 40% of the total flow rate of raw water to the expiratory storage tank 40.

Here, the received flow rate of the first flow tank 10 and the raw water supply flow rate flowing from the first flow tank 10 to the expiratory storage tank 40 are the amount of carbon required in the process of denitrification of the raw water accommodated in the expiratory storage tank 40 It is determined by a numerical value corresponding to.

The second flow tank 20 is a device through which the rest of the raw water consisting of contaminated water flows in, and accommodates 60 to 90% of the total flow of raw water. In addition, the second flow tank 20 supplies 60 to 90% of the total flow rate of raw water to the pressurized exhalation tank 30.

The pressurized exhalation tank 30 is connected to the second flow tank 20 and the second pipe 130, and the air dissolution rate increases as the raw water of the second flow tank 20 injected by pumping is pressurized inside. You will receive the enemy who has become. To this end, a high pressure pump 80 and an ejector 90 may be installed in the second pipe 130. The high pressure pump 80 pumps raw water from the second flow tank 20 and puts it into the pressurized exhalation tank 30. Here, the pressurized exhalation tank 30 according to an embodiment of the present invention maintains an internal pressure of 2 to 7 kg/cm ² .

The ejector 90 is disposed at the rear of the high pressure pump 80 and is introduced into the pressurized exhalation tank 30 by mixing air introduced from the outside with raw water.

In addition, the pressurized exhalation tank 30 accommodates microorganisms therein. As the raw water is oxidized and decomposed by the adsorption of the microorganisms and raw water, the treated water undergoing luxury uptake and nitrification of phosphorus is generated.

Here, the pressurized exhalation tank 30 according to the embodiment of the present invention is composed of a plurality of partition wall layers 32 formed by a plurality of partition walls 31 that are horizontally spaced apart in the vertical direction as shown in FIG. 2, A large amount of microorganisms are attached to the sponge filter material layer 33 disposed in each partition layer 32 to maintain a high MLSS (mixed liquer suspended solid), and as the oxidation and decomposition efficiency of raw water increases, excessive intake of phosphorus to the raw water ( luxury uptake) and nitrification efficiency.

Meanwhile, as the flow rate of air flowing into the pressurized exhalation tank 30 is controlled through the ejector 90, the nitrification and nitrification of organic matter in the pressurized exhalation tank 30 can be properly maintained. And as the expiratory storage tank 40 is connected to the second pipe 130 through the fifth pipe 160, the raw water is not supplied from the second flow tank 20 to the pressurized expiration tank 30 or the raw water is supplied. When this is not possible or in order to further increase the treatment efficiency, it is possible to increase the efficiency of the luxury uptake and nitrification of phosphorus while introducing the treated water from the exhalation storage tank 40 into the pressurized exhalation tank 30.

Through the structure of the pressurized exhalation tank 30 as described above, the blower and the diffuser may be removed, and the size of the internal space of the pressurized exhalation tank 30 may be reduced. Through this, it is possible to improve economy and contaminated water treatment efficiency.

The expiratory storage tank 40 is connected to the pressurized exhalation tank 30 and the third pipe 140 while being connected to the first flow tank 10 and the first pipe 120 to The raw water from the first flow tank 10 is supplied and mixed and stored. Here, the expiratory storage tank 40 uses the raw water of the first flow tank 10 as a carbon supply source so that the first denitrification of the treated water of the pressurized aerobic tank 30 proceeds. In addition, the expiratory storage tank 40 allows some air bubbles in the treated water to be removed during the mixing process between the treated water in the pressurized exhalation tank 30 and the raw water in the first flow tank 10 while the remaining air bubbles in the treated water are dispersed into the atmosphere. do. In addition, the aerobic storage tank 40 prevents the loss of sludge by attaching a part of the sludge contained in the treated water to the internal space. To this end, the aerobic storage tank 40 according to the embodiment of the present invention is provided with a piece sponge network 41 Is done. One or more pieces of sponge net 41 are disposed horizontally on the top of the aerobic storage tank 40, and a part of the sludge contained in the treated water is attached to prevent the loss of the sludge while the bubbles dissolved in the pressurized exhalation tank 30 Remove.

Meanwhile, the treated water of the pressurized exhalation tank 30 and the raw water of the first flow tank 10 flow into the lower portion of the expiratory storage tank 40 and proceed in an upflow. Through this, the mixing efficiency between the treated water in the pressurized exhalation tank 30 and the raw water in the first flow tank 10 can be increased.

In particular, in the expiratory storage tank 40 according to the embodiment of the present invention, the third pipe 140 is disposed horizontally under the expiratory storage tank 40, and is arranged in a shape wound toward the center from the lower edge of the expiratory storage tank 40 On the other hand, the size is gradually reduced toward the center of the structure to prevent the occurrence of dead space in the lower portion of the expiratory storage tank 40.

The complex treatment tank 50 is connected to the aerobic storage tank 40 and the fourth pipe 150 so that the treated water from the aerobic storage tank 40 is put into the inner cylinder 58, and proceeds to the upstream, thereby secondary denitrification and sludge. It is a device in which precipitation is carried out. Here, according to the operation of the pump 100' and three valves installed under the complex treatment tank 50, it may be connected to the thickening tank 60 through the sixth pipe 170 when necessary, and the thickening tank 60 is a complex treatment It is a device that receives and discards phosphorus-containing microorganisms contained in the concentrated sludge of the tank 50.

Meanwhile, the complex treatment tank 50 allows the treated water to be returned to the first flow tank 10 and the second flow tank 20 through the seventh pipe 180.

In addition, the treated water from the expiratory storage tank 40 is put into the upper inner cylinder 58 of the complex treatment tank 50 and descends to the lower portion of the inner cylinder 58 by non-pressure flow, and then exits from the inner cylinder 58 and proceeds upward. , The complex treatment tank 50 according to the embodiment of the present invention has a weir structure in which the outlet 53 is formed at a set height.

In particular, the interior of the complex treatment tank 50 according to the embodiment of the present invention is divided into a first area 54, a second area 55, and a third area 56.

The first area 54 constitutes the upper part of the complex treatment tank 50, and the treated water is supplied to the inner cylinder 58 from the expiratory storage tank 40 and the fourth pipe 150, and is passed through a non-pressure flow. It moves from 58 to the bottom and moves upstream, and the discharge port 53 is formed at the set height, so that the treated water is discharged.

The second area 55 forms the middle part of the complex treatment tank 50, is formed as an oxygen-free area, and a mixer 51 connected to the motor 52 is arranged vertically through mixing of the treated water. It is an area that induces denitrification.

The third area 56 forms the lower part of the complex treatment tank 50, where sludge is deposited and accumulated, and the first flow tank 10 and the second flow tank 20 through the seventh pipe 180 This is an area where the furnace treated water is conveyed or the external thickening tank 60 is connected through the sixth pipe 170.

As the functions of the anaerobic tank and the anoxic tank in the conventional system as described above are performed in the complex treatment tank 50 performing the precipitation function, the biological advanced water treatment system 1 using the pressure tank according to the embodiment of the present invention Economic feasibility increases.

The biologically advanced water treatment system 1 using the pressure tank according to the embodiment of the present invention configured as described above is provided through a pressurized aeration tank having a structure capable of increasing the efficiency of oxidation and decomposition of contaminated water, the activity of microorganisms, and the oxidation-nitrification of organic matter. While allowing the use of a tank with a reduced internal space size, the aerobic tank, blower, and air diffuser provided as essential components of the conventional high-level biological water treatment facility are removed, and the internal transport is omitted. It makes it possible to perform luxury uptake and nitrification of phosphorus with high treatment efficiency. Through this, the biologically advanced water treatment system 1 using a pressure tank according to an embodiment of the present invention can reduce energy consumption, installation, and maintenance costs, thereby improving economy and efficiency.

As described above, a biological advanced water treatment system using a pressure tank according to an embodiment of the present invention has been illustrated according to the above description and drawings, but this is merely an example and within the scope not departing from the technical idea of the present invention. It will be appreciated by those skilled in the art that various changes and modifications are possible.

1: Advanced biological water treatment system using pressure tank
10: first flow tank
20: second flow tank
30: pressurized exhalation tank
31: bulkhead
32: bulkhead layer
33: sponge filter material layer
40: expiratory storage tank
41: piece sponge net
50: complex treatment tank
51: mixer
52: motor
53: outlet
54: first area
55: second area
56: third area
57: scraper
58: inner cylinder
60: thickening tank
80: high pressure pump
90: ejector
100, 100': pump
110a, 110b, 110c, 110d, 110e: on/off valve
120: 1st pipe
130: 2nd pipe
140: 3rd pipe
150: 4th pipe
160: 5th pipe
170: 6th pipe
180: 7th pipe

Claims (5)

A first flow tank 10 into which a part of raw water made of contaminated water flows;
A second flow tank 20 into which the rest of the raw water made of contaminated water flows;
It is connected to the second flow tank 20 and the second pipe 130, and the raw water of the second flow tank 20 injected by pumping is pressurized to maintain an internal pressure of 2 to 7 kg/cm ² The raw water with increased dissolution rate is accommodated, microorganisms are accommodated therein, and the raw water is oxidized and decomposed by adsorption of the microorganisms and raw water to generate treated water with luxury uptake and nitrification of phosphorus. A pressurized exhalation tank 30;
It is connected to the pressurized exhalation tank 30 and the third pipe 140, while being connected to the first pipe 120 of the first flow tank 10, the treated water of the pressurized exhalation tank 30 and the first The raw water of the flow tank 10 is supplied and stored in a mixture, and the raw water of the first flow tank 10 is used as a carbon source for the first denitrification of the treated water of the pressurized exhalation tank 30. ) Proceeds, and in the mixing process between the treated water of the pressurized exhalation tank 30 and the raw water of the first flow tank 10, some bubbles in the treated water are removed while the remaining bubbles in the treated water are dispersed into the atmosphere. , An aerobic storage tank 40 for preventing the loss of sludge by attaching a portion of the sludge contained in the treated water to the inner space;
It is connected to the expiratory storage tank 40 and the fourth pipe 150 so that the treated water of the expiratory storage tank 40 is input and divided into a first area 54, a second area 55, and a third area 56. As the second denitrification and sludge sedimentation proceeds, the anaerobic tank and the anoxic tank are performed, and are treated with the first flow tank 10 and the second flow tank 20 through the seventh pipe 180 A complex treatment tank (50) that allows water to be returned to realize anaerobic conditions for excessive phosphorus intake;
It is installed in the second pipe 130 and pumps raw water from the second flow tank 20 and puts it into the pressurized exhalation tank 30 in a pressurized state, so that the pressurized exhalation tank 30 is transferred to a high pressure pump 80 );
Includes; an ejector 90 installed in the second pipe 130, disposed behind the high pressure pump 80, and mixing air introduced from the outside with raw water and introducing it into the pressurized exhalation tank 30; Consists of
The first area 54 of the complex treatment tank 50 forms an upper part, and the treated water is supplied to the inner cylinder 58 from the expiratory storage tank 40 and the fourth pipe 150 to be a non-pressure flow. It moves from the inner cylinder 58 to the bottom and moves upstream, and the discharge port 53 is formed at a set height to flow out the treated water, and the second area 55 of the complex treatment tank 50 is a middle portion It is an area formed as an oxygen-free zone, and a mixer 51 connected to the motor 52 vertically is arranged to induce denitrification through mixing of treated water, and the third area of the complex treatment tank 50 The area 56 forms the lower part, and the sludge is deposited and accumulated, and the treated water is returned to the first flow tank 10 and the second flow tank 20 through the seventh pipe 180 or an external thickening tank ( 60) is an area connected through the sixth pipe 170,
Treatment of the pressurized exhalation tank 30 through the third pipe 140 in which one end is connected to the upper portion of the pressurized exhalation tank 30 and the other end is horizontally disposed under the exhalation storage tank 40 Water is introduced into the exhalation tank 40 by the pumping operation of the high pressure pump 80 and the internal pressure of the pressurized exhalation tank 30, and the third pipe 140 is the lower edge of the exhalation storage tank 40. It is arranged in a shape that is wound toward the center from the side and gradually decreases in size toward the center to prevent the occurrence of dead space under the expiratory storage tank 40. Advanced biological water treatment system. The method of claim 1,
The pressurized exhalation tank 30 is composed of a plurality of partition wall layers 32 formed by one or more partition walls 31 that are spaced vertically and horizontally arranged, and a sponge filter material layer disposed on each partition wall layer 32 A biological advanced water treatment system, characterized in that a large amount of microorganisms are attached to (33) to increase the efficiency of the luxury uptake and nitrification of phosphorus to the raw water. delete The method of claim 1,
The expiratory storage tank 40,
It is disposed at the top, characterized in that it comprises a piece of sponge net 41 for preventing the loss of sludge by attaching a portion of the sludge contained in the treated water while removing air bubbles dissolved in the pressurized exhalation tank 30. Advanced biological water treatment system. delete

Images