KR200255001Y1 - System for purifying waste water - Google Patents

Abstract

The present invention relates to a wastewater purification system that can improve the quality of rivers by purifying wastewater regardless of the variation in the amount of water to be treated, and at a relatively low installation and maintenance cost. The wastewater purification system according to the present invention has a plurality of wastewater treatment structures installed at different heights such that the first wastewater treatment structure is located at the highest position adjacent to the wastewater source; The waste water treatment structure includes a plurality of water barrier walls for forming a pair of water holes for receiving waste water and some purified water; A waste water purifying unit located at a lower portion of the first puddle of the pair of water pools, and configured to purify contaminants contained in the waste water; And a sludge receiving pond formed below the water inlet side of each water barrier wall to accommodate sludge settled from the waste water entering the waste water purification unit; The purified water from the wastewater purification unit enters the second pool of water pairs.

Description

System for purifying waste water

The present invention relates to a wastewater purification system, and more particularly, to treat wastewater as a contact media in a multi-step manner using a contact media, while passing through the contact media so that the culture of microorganisms in the waste water passing through the contact media can be activated. It relates to a waste water purification system having a structure for injecting air into the waste water.

As is well known, domestic rivers have severe water deterioration due to nutrients such as nitrogen and phosphorus contained in fertilizers, livestock wastewater, domestic sewage and factory wastewater, and consequently, rivers, lakes and seas where contaminated water meets in rivers. Green algae and red algae occur in the natural ecosystems. Water eutrophicated by nutrients contained in the wastewater of rivers causes the algae to thrive in the water surface such as green algae, red tide, and the like. When algae thrives on the surface of the water, it blocks the sun's rays to the water, inhibiting the photosynthesis of aquatic plants and lowering the oxygen dissolution rate in the water, thus losing the self-cleaning ability of the water system.

Therefore, the oxygen supply of the water is interrupted by the green algae and the red tide generated by eutrophication of the water, and it is often encountered in the case that the fish wastewater inhabiting the water is dead. In particular, when a red tide phenomenon occurs in a water supply source, a problem of odor caused by algae occurs and the high water purification treatment must be performed. Excessive chlorine disinfection used in this deodorant treatment can lead to the presence of trihalomethane (THM), a highly toxic substance in the water. In Korea, green algae and red tide occur annually in the spring and autumn. Damage is occurring.

Therefore, in addition to the removal of algae caused by eutrophication of water in rivers, rivers, lakes and the sea, there is an urgent need for water purification measures for non-point sources.

On the other hand, in order to fundamentally improve the water quality of rivers, it is fundamentally not to discharge pollutants into rivers, rivers, lakes and seas, to purify water quality from sources of pollutants, and to treat wastewater of polluted streams, There is a method of transferring to a wastewater treatment plant for treatment.

Of the above methods, it is best not to discharge pollutants into rivers, rivers, lakes, and seas, but this is practically impossible, and purifying water from sources of pollutants is the next best option, but for many pollutant sources Installing a clarifier or transferring contaminated sewage, wastewater to sewage and wastewater treatment plants is costly. In addition, in the case of point pollutants, the problem is relatively small, but in the case of nonpoint pollutants, there is no special treatment for water treatment.

As a wastewater treatment apparatus for rivers, Patent Publication No. 93-23280 relates to an apparatus for purifying polluted river water using a charcoal layer and a gravel layer, and a technology related to a biofilm river purification apparatus using waste concrete or waste tires. This patent is disclosed in Japanese Patent Laid-Open Nos. 97-20976 and 97-20977. In addition, Japanese Patent Application Laid-Open No. 99-24172 describes a method for purifying a river using a microbial contact material. Further, Japanese Patent Laid-Open Nos. 95-26882 and 95-24975 describe a device for supplying oxygen to a stream to preserve the ecosystem of the stream.

However, the method of filtration, biooxidation, or aeration purification is fundamentally limited in rivers with high flow rates and high yields.

Patent Publication No. 99-24236 relates to a water purification system using a water channel, and describes a system for installing a water channel on one side of a lake to inhale the raw water of the lake with an absorption pipe, moving it to the water channel, and generating and purifying ultra-bubbles. have. However, this system uses only very fine bubbles without agglomeration process with flocculating chemicals, and thus, it is difficult to sufficiently support fine suspended matter or contaminants, and power is also consumed because raw water must be sucked into the absorption pipe. In addition, this system has to draw the raw water into a narrow water channel, so that it is difficult to process the entire water system to be treated, and there is a problem that the purification effect is insignificant in the case of a sudden change in water quality or an increase in yield.

In order to solve the problems as described above, Patent Publication No. 2001-38085 is installed between the two eyes of the river as shown in Fig. 1 and 2 to install the underwater structure to be located in the water below 1-5m from the bottom or the water surface In the upstream side of the structure, the chemical injection device 22 for injecting the coagulated drug pumped by the drug pump 22 to inject the coagulant drug stored in the drug tank 20 into the river water, and the coagulant drug and the water to be treated. A stirring device or a high pressure water injection device 23 for stirring the pressure is provided, and a pressurized water injection device 33 containing dissolved air is installed downstream of the structure. In addition, a guide float 13 is provided from a downstream side of the pressurized water injection device 33, and a scum collection device 40 and a dewatering device 41 are provided to extend with the guide float 13.

In such a device, suspended solids in water react with the flocculant to form flocs. Injection of the flocculating chemicals is supplied by the chemical injector 22 using the chemical pump 21 from the chemical tank 20. The floc formed by the injection of the flocculating chemicals adheres to the fine bubbles of dissolved air and floats to the surface of the water system. That is, by pumping the pressurized pump 30 to store the treated water or a part of the treated water in the pressurized tank 32, the dissolved air is sufficiently saturated in the water stored in the pressurized tank 32 using the compressor 31. The internal pressure of the pressurizing tank 32 is pressurized to 3 atmospheres or more, preferably 4-7 atmospheres. Thereafter, the pressurized water in which dissolved air is saturated is injected into the river water through the pressurized water injection device 33.

Therefore, the air dissolved in the pressurized water is rapidly depressurized to below atmospheric pressure, so that fine air bubbles are formed in the river water, and flocs, suspended matter, algae, etc. of the river water are attached to the air bubbles and float above the water surface with the air bubbles. The scum that floats above the water (collectively, algae, suspended matter, contaminants, etc.) that has risen to the surface is collected by the scum collection device 40 and dewatered by the dehydration device 41 and then processed.

However, the conventional wastewater purification apparatus as described above, because the amount of water to be treated and the flocculating agent used for the treatment of the water, and the capacity of the various pumps must always be properly maintained with the amount to be treated, such as drought or heavy rainfall In the case where the quantity of water varies, there is a problem in that the wastewater of the river cannot be purified properly.

In addition, in addition to the construction of an underwater structure, because a lot of equipment is used with the use of chemicals to purify the water quality of the river, there was also a problem that the installation and maintenance costs are high.

Therefore, an object of the present invention is to provide a waste water purification system that can improve the water quality of the stream by purifying the waste water irrespective of the variation of the water to be treated.

It is an object of the present invention to provide a wastewater purification system having a relatively low installation and maintenance cost.

1 and 2 schematically show the structure of a conventional wastewater purification apparatus.

3 is a view showing a waste water purification system of the present invention.

4 and 5 show examples of purification means used in the wastewater purification system shown in FIG.

6 is a view showing a connection structure of the purification means used in the wastewater purification system according to the present invention.

(Explanation of symbols for the main parts of the drawing)

1a-1n: water barrier 2: purification means

3: sludge storage pond 4: air inlet

5: air outlet 6: sludge receiving space

7: casing 8: media layer

9: wastewater purification unit 10: soil layer

14 pipe 15 air vent

20: flange 25: settling groove

100a, 100b: Puddle of water N ₁ ~ N _i : Wastewater treatment structure

The object as described above has a plurality of wastewater treatment structures installed at different heights such that the first wastewater treatment structure is located at the highest position adjacent to the wastewater source; The waste water treatment structure includes a plurality of water barrier walls for forming a pair of water holes for receiving waste water and some purified water; A wastewater purification unit located at a lower portion of the first puddle among the pairs of water and for purifying contaminants contained in the wastewater; And a sludge receiving pond formed at the bottom of the water inlet side of each water barrier wall to accommodate the sludge settled from the wastewater entering the wastewater purification unit. The water purified by the wastewater purification unit may be achieved by the wastewater purification system according to the present invention, characterized in that the water flows into the second puddle of the pair of waterholes.

In the above, the wastewater purification unit includes a plurality of purification means arranged in series to gradually purify the wastewater.

Each purifying means includes a pair of air inlets connected to an air generating device in front of and below the waste water, a casing having an air outlet at the top of the waste water discharge side, and a sludge accommodating portion provided inside the casing to communicate with the air inlet. And a plurality of media layers stacked on top of the sludge receiving space to communicate with the air inlet and formed of an air permeable media material.

In the above, air inlets are provided at the open end of the pipe in which a plurality of vents are formed, the pipe passing through the casing at the bottom of the plurality of media layers.

The casings are flanged at one end and joined to each other by receiving the other end of the adjacent casing in the flange.

The air outlet is formed in an inverted U-shape to prevent soil and water from entering the casing.

The media layer is composed of media consisting of crushed stone, sand or silica sand.

The casing is formed of a square or circular cylinder.

Alternatively, an object as described above may comprise a plurality of water barrier walls for forming a pair of water holes for receiving some purified water; A wastewater provided at the bottom of the first puddle of the pair of puddle and having a plurality of media arranged in series to gradually purify the wastewater during the passage of the wastewater, and sending the purified wastewater to the second puddle Purifying unit; And a sludge receiving pond formed in the bottom of the water inlet side of the water barrier wall to accommodate sludge settled from the wastewater entering the wastewater purification unit.

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

3 is a view showing a waste water purification system of the present invention. As shown in FIG. 3, the wastewater purification system according to the present invention includes a plurality of wastewater purification units N ₁ to N _i . Therefore, it is possible to appropriately arrange the number of waste water purification units N ₁ to N _i in accordance with the amount of waste water to be treated.

First, as shown in FIG. 3, the first wastewater purification unit N ₁ is disposed adjacent to a wastewater source such as a river, a factory wastewater, a livestock wastewater, or an apartment, and is located higher than the next wastewater purification unit N ₂ . Is located in.

Each wastewater treatment structure N ₁ to N _i blocks a wastewater to flow to the next wastewater treatment structure N ₂ to N _{i + 1} while forming a pair of puddles 100a and 100b. With walls 1a, 1b, 1c, the water barrier walls 1a, 1b, 1c form a puddle 100a, 100b for receiving water therebetween as can be seen from the figure. The water stored in the puddle 100a, 100b formed in the water barrier walls 1a, 1b, 1c has a difference in the water level by the difference in the height of the water barrier walls 1a, 1b, 1c.

Under the water barrier walls 1a, 1b, 1c, sludge receiving ponds 3 are provided, respectively, for receiving sludge (sludge) generated from a wastewater source or a wastewater channel contained in each of the waterholes 100a, 100b. The sludge settled in the sludge receiving ponds 3 is separated out and dewatered by means such as a pump and then incinerated or landfilled or recycled to other resources.

1, the waste water processing structure (N ₁ ~ N _i) the waste water for purifying process in the waste water purification unit 9 is such a dam wall (1a, 1b) puddle (100a, 100b) formed by the At the lower part of the first puddle (100a) of the sludge receiving puddle (3) is provided. The waste water purification unit 9 is open to the second puddle (100b) of the puddle (100a, 100b) of the end surface side of the waste water inflow so that the waste water is introduced as shown in FIG. Therefore, the water purified by the wastewater purification unit 9 flows into the water puddle 100b formed by the water barrier walls 1b and 1c.

By continuously supplying water to the water puddles 100a, 100b formed by the water barrier walls 1a, 1b, 1c, the water passes over the water barrier walls 1a, 1b, 1c to the next wastewater treatment structure N _2. , N _4, N ₆ ...) to the flow, the waste water processing structure _{(N 2, N 4, N} 6 ...) to the flowing water is again each waste water processing structure _{(N 2, N 4, N} 6 .. It is purified by passing through the waste water purification section 9 provided in. As described above, the structure in which the wastewater purification unit 9 is provided only in one of the two pools 100a and 100b is provided with the wastewater purification unit 9 continuously in each wastewater treatment structure. This prevents water from flowing to the next wastewater treatment structure N ₂ , N ₄ , N ₆ . It is to.

With the structure as described above, the wastewater or purified water introduced into the water puddle 100a may be introduced into the wastewater purification unit 9 by its water pressure, and the wastewater purification unit 9 may be wastewater or partially purified water. As water passes through, it cleans up contaminants in the water. Partially purified water in each wastewater purification section 9 is discharged to the second puddle 100b formed by the water barrier walls 1b and 1c, and the final purified water in the final wastewater purification section 9 is flowed into the stream. Discharged.

On the other hand, the bottom of the puddle (100a, 100b) formed by the water barrier walls (1a, 1b, 1c), as shown in Figure 3 so that more water pressure acts on the sludge receiving pond (3). The slant receiving pond 3 is formed in a downward slope from 1a, 1b, 1c, and the bottom end point of the slope bottom is a wastewater discharge side upper end of the wastewater purification unit 9. Therefore, just above the sludge receiving pond 3 has a structure that is open to a water pool.

The waste water purification section 9 as described above preferably comprises a plurality of purification means 2 arranged in series to gradually purify the waste water, which purification means 2 are shown in FIGS. 4 and 5. It has a casing (7) formed of a rectangular or circular cylinder, such a casing (7) is provided with a pair of air inlets (4) connected to an air generating device such as an air compressor in the front and rear lower, while the waste water discharge side It has an air outlet 5 at the top.

These air inlets 4 are provided at both open ends of the pipe 14 in which a plurality of vents 15 are formed. Therefore, the air supplied from the air inlet 4 is supplied into the casing 7 through the vent 15 formed in the pipe 14. On the other hand, the casings 7 are provided with a flange 20 at one end portion such that the casings 7 can be coupled to each other as shown in FIG. 6, so that the other end of the casing 7 is flanged ( 20) By inserting in, the casings 7 can be joined together. The flange 20 is provided with a groove 25 so that an air supply pipe (not shown) connected to the air inlet 4 can be placed. The groove 25 may also be formed as a through hole to fix the air supply pipe.

On the other hand, the air discharge port 5 is provided on the upper side of the waste water discharge side, the air discharge port 5 provided on the upper side of the waste water discharge side of the casing 7 is buried in the soil layer 10 forming the bottom of the puddle or in the puddle Exposed to the water received. In order to prevent the soil or water from penetrating or flowing back into the casing 7 through the air outlet 5 by the air outlet 5 being embedded in the soil layer 10 or exposed to water, the air outlet 7 Is preferably formed in an inverted U shape. In addition, since there is a difference in the water surface of the river or each water hole, there is a pressure difference in the water pressure acting on the river and each water hole, and by such pressure difference, the soil or water flows through the air outlet 7 through the casing ( 7) It is prevented from penetrating or refluxing into.

The lower part of the casing 7 is provided with a sludge accommodating space 6 in the lower part for accommodating sludge generated while the waste water or some purified water passes through the waste water purification unit 9, and the sludge accommodating space 6 The upper part is laminated with a plurality of contact media layers 8 for filtering contaminants contained in the waste water or part of the purified water by contact with the waste water or part of the purified water during passage of the waste water or part of the purified water.

This contact media layer 8 is laminated on top of the sludge receiving space 7 to communicate with the air inlet 4 and is formed of an air permeable media material, which media layer 8, as is well known, Media consisting of sand, silica sand, charcoal, biofilters and / or activated charcoal may be used. These media are permeable to the air introduced into the casing 7 through the air inlet (4), the contaminants contained in the waste water or some purified water purified by the media layer 8 with the air permeation. It is sludged and settled in the sludge accommodating space 6 provided in the lower part of the casing 7, and is accommodated in the sludge accommodating space 6. The sludge settled in the sludge accommodating space 6 is removed to the outside by means such as a pump and regenerated so that it can be used for incineration, landfill or elsewhere as described above.

On the other hand, the microorganisms inhabiting the media layer 8 provided to the casing 7 by the air introduced into the casing 7 through the air vent 15 formed in the pipe 14 from the air inlet 4 is better cultured. Such microorganisms may further increase the purification efficiency of contaminants contained in waste water or some purified water. In addition, these microorganisms may be evenly supported throughout the media layer 8 by the air supplied from the bottom into the casing 7.

In the wastewater purification system according to the present invention, the number of wastewater treatment structures may be appropriately arranged according to the amount of water to be purified, and it is usually preferred that the number be determined according to the maximum amount of water to be treated.

According to the wastewater purification system according to the present invention as described above, by properly arranging the wastewater treatment structure, it is possible to improve the water quality of the stream by purifying the wastewater irrespective of the variation in the quantity of the wastewater to be treated.

Furthermore, after installation, only the means for removing the sludge contained in the sludge receiving pond and the sludge receiving space in the casing and injecting air into the casing are required, so that the installation and maintenance costs are relatively low compared with the conventional purification apparatus. Has

In addition, by being installed in wastewater sources such as rivers, factory wastewater, animal husbandry wastewater or apartments, it has the advantage that the range of use is wider than conventional purification apparatuses limited to any one place.

Claims (7)

The first wastewater treatment structure has a plurality of wastewater treatment structures installed at different heights such that it is located at the highest position adjacent to the wastewater source; The wastewater treatment structure includes: a plurality of water barrier walls for forming a pair of puddles for receiving wastewater and some purified water; A wastewater purification unit located at a lower portion of the first puddle among the pairs of water and for purifying contaminants contained in the wastewater; And A sludge receiving pond formed at a lower portion of the water inlet side of each water barrier wall to accommodate sludge settled from the wastewater entering the wastewater purification unit; Waste water purification system, characterized in that the purified water from the waste water purification unit is introduced into the second water hole of the pair of water holes. The wastewater purification system according to claim 1, wherein the wastewater purification section includes a plurality of purification means arranged in series to gradually purify the wastewater. The method according to claim 2, wherein each purification means, A pair of air inlets connected to the air generating device in the front and rear of the waste water, the casing having an air outlet on the upper side of the waste water discharge, A sludge receiving space provided inside the casing to communicate with the air inlet, And a plurality of media layers stacked on top of the sludge receiving space and formed of an air permeable media material to communicate with the air inlet. 4. The wastewater purification system according to claim 3, wherein the air inlets are provided at an open end of a pipe in which a plurality of vents are formed, the pipe passing through the casing at the bottom of the plurality of media layers. 4. The wastewater purification system according to claim 3, wherein the casings are flanged at one end, and the other ends of adjacent casings are coupled to each other by being accommodated in the flanges. 4. The wastewater purification system according to claim 3, wherein the media layer is composed of media consisting of crushed stone, sand or silica sand. A plurality of clam walls to form a pair of puddle to receive some purified water; A wastewater provided at the bottom of the first puddle of the pair of puddle and having a plurality of media arranged in series to gradually purify the wastewater during the passage of the wastewater, and sending the purified wastewater to the second puddle Purifying unit; And And a sludge receiving pond formed at the bottom of the water inlet side of the water barrier wall to accommodate sludge settled from the wastewater entering the wastewater purification unit.