KR100456449B1 - A waste water disposal system - Google Patents

Abstract

The present invention relates to a wastewater treatment system for effectively removing organic substances that were not treated with chemicals only in a conventional wastewater treatment system by installing a filtration device in a conventional wastewater treatment system.

A raw water storage tank, a raw water transfer pump for transferring wastewater stored in the raw water storage tank to the outside, a chemical tank provided separately, and each of the raw water storage tanks are connected to an agitator, and the wastewater and chemicals supplied from each tank are mixed in an agitator. Chemical treatment device to form the sludge, sludge treatment device for processing the sludge transferred from the chemical treatment device to store in the concentration tank, dewatering and discharged sludge stored in the concentration tank and transfer the treated water back to the raw water storage tank In the wastewater treatment system consisting of a dehydrator,

A separate feed pipe is connected to the primary treated water storage tank of the sludge treatment apparatus, and is installed on the conveyed pipe to treat organic substances contained in the primary treated water by a filtration method by a filter. The guide member 24, the drain guide member 25, the cylinder 26, the filter 27 and the fixed plate 28 is composed of.

Description

A waste water disposal system

The present invention is to compensate for the shortcomings of the conventional wastewater treatment system that can not remove the organic material only with chemicals, and to provide a wastewater treatment system to effectively remove the organic material by additionally installing a filtration device in the conventional wastewater treatment system will be.

In general, industrial wastewater and wastewater are treated through physical, chemical, and biological treatments, and as environmental pollution is intensified, secondary and tertiary treatment facilities (e.g., ultrafiltration, membrane, ion exchange resin, etc.) ) Is being installed as a countermeasure, and these newly installed treatment facilities still have many problems, such as high installation costs and high overall processing costs due to frequent replacement of filters.

1 is a conceptual view showing a conventional wastewater treatment system 1, which is a raw water storage tank 2, a raw water transfer pump 3 for transferring wastewater stored in the raw water storage tank 2 to the outside; Each of the chemical tank 4 and the raw water storage tank 2, which are separately provided, is connected to the stirrer 5, and the waste water and the chemicals supplied from each of the tanks 2 and 4 are mixed in the stirrer 5 to form a sludge. Chemical treatment apparatus 6 to be formed, sludge treatment apparatus 9 for treating the sludge transferred from the chemical treatment apparatus 6 in the collecting tank 7 and storing it in the concentration tank 8, stored in the concentration tank 8 It is composed of a dehydrator 10 for dewatering and discharging the sludge and transferring the treated water back to the raw water storage tank (2).

In this conventional wastewater treatment system 1, the raw water transfer pump 3 supplies wastewater stored in the raw water storage tank 2 to the agitator 5 of the chemical treatment apparatus 6, and at the same time, a separate supply pump 6a. When supplying the chemical stored in the chemical tank (4) to the stirrer (5), the propeller (5a) of the stirrer (5) is rotated to mix the supplied waste water and the chemical.

As such, when the waste water and the chemical are mixed, the waste water forms sludge by chemical reaction of the chemical, and the sludge is transferred to the sludge treatment apparatus 9, and the sludge treatment apparatus 9 collects the transferred sludge. Stored in the concentration tank (8) and the treated water is discharged or transferred back to the raw water storage tank (2), the sludge stored in the concentration tank (8) is dehydrated by the dehydrator (10), the turbid treatment water generated at this time It will be repeatedly processed to feed the raw water storage tank (2).

However, the chemicals used to treat the wastewater use polymers, caustic soda and ferrous sulfate powders, but these chemicals are particularly resistant to organic substances (reactive dyes) contained in waste dyestuffs that have been dyed with cloth. There was a drawback that could not be handled.

In addition, since the organic materials (BOD, COD) are the main causes of environmental pollution, the environmental law requires the treatment to be complete so as to specify the treatment standard value.

However, in the conventional wastewater treatment system, since most of the old facilities installed before the environmental law is enacted, the wastewater is treated using only chemical treatment, and thus, the organic material cannot be treated beyond the standard set by the law, causing environmental pollution.

Therefore, in order to prevent such environmental pollution, it is necessary to newly install secondary and tertiary treatment facilities, such as ultrafiltration, separation membrane, and ion exchange resin, which are expensive to install and difficult to operate and manage. It was.

Accordingly, the present invention is to compensate for the shortcomings of the conventional wastewater treatment system that can not remove the organic material only by the chemical, wastewater treatment system to effectively remove the organic material by additionally installing a filtration device in the conventional wastewater treatment system. The purpose is to provide.

The wastewater treatment system includes a raw water storage tank, a raw water transfer pump for transferring wastewater stored in the raw water storage tank to the outside, a chemical tank provided separately, and each of the raw water storage tanks are connected to an agitator, and the wastewater and chemicals supplied from these tanks. To a sludge by mixing in a stirrer, a sludge treatment apparatus for treating and storing the sludge transferred from the chemical treatment apparatus, the sludge stored in the concentration tank is dewatered and discharged, and the treated water is discharged again In the wastewater treatment system consisting of a dehydrator for transferring to a storage tank,

A separate transport pipe is connected to the primary treated water storage tank of the sludge treatment device, and is installed on the transport pipe to filter organic materials contained in the treated water by a filtration method by a filter. to be.

Here, the filtration device is an inlet guide member having an inlet; A drain guide member having an outlet; A cylinder having both sides penetrated therein and connected to both sides of the inlet guide member and the drain guide member so as to communicate with each other; At least one filter having a hollow pipe-shaped body having an opening at one end thereof and installed inside the cylinder to filter sludge and reactive dyes contained in the treated water passing through the cylinder; And a fixing plate accommodated in the drain guide member to be liftable and fixing the opening of the filter.

1 is a conceptual diagram of a wastewater treatment system according to the related art

2 is a conceptual diagram of a wastewater treatment system according to the present invention;

Figure 3a is a front sectional view of an embodiment of a filtration device according to the present invention

Figure 3b is a front sectional view of another embodiment of a filtration device according to the present invention

Figure 4 is a front sectional view showing the inside of the filter of the filtration device according to the invention

5 is a perspective view showing the inside of the filter of the filtering device according to the present invention;

Figure 6 is a plan view showing a fixed plate of the filtration device according to the invention

7 is a plan view showing a diaphragm of the filtration device according to the invention

Explanation of symbols on the main parts of the drawings

2: raw water storage tank 3: raw water feed pump

6: chemical treatment device 9: sludge treatment device

10: dehydrator 21: filtration device

24: acquisition guide member 25: drainage guide member

26: cylinder 28: fixed plate

30: plate 31: vibration motor

Hereinafter, on the basis of the accompanying drawings will be described in detail the wastewater treatment system according to the present invention.

2 is a conceptual diagram of a wastewater treatment system according to the present invention, Figure 3a is a front sectional view of one embodiment of a filtration device according to the present invention, Figure 3b is a front sectional view of another embodiment of a filtration device according to the present invention.

As shown in the drawings, the wastewater treatment system of the present invention uses the conventional wastewater treatment system 1 as it is, and installs a filtration device 21 separately manufactured in the conventional wastewater treatment system 1 to effectively remove organic substances. will be.

Thus, the conventional wastewater treatment system (1) applied to the present invention is a raw water storage tank (2), a raw water transfer pump (3) for transferring the wastewater stored in the raw water storage tank (2) to the outside, a chemical tank provided separately ( 4) and the raw water storage tank (2) are each connected to the stirrer (5) and the chemical treatment apparatus for mixing the waste water and the chemical supplied from each of the tank (2) (4) in the stirrer (5) to form sludge (6), the sludge treatment apparatus 9 for treating the sludge transferred from the chemical treatment apparatus 6 and storing the sludge in the concentration tank 8, dewatered and discharged the sludge stored in the concentration tank 8, and the treated water again It consists of a dehydrator (10) for transferring to the raw water storage tank (2).

In this conventional wastewater treatment system 1, in the wastewater treatment system of the present invention, a separate transfer pipe 22 is connected to the primary treated water storage tank 9a of the sludge treatment apparatus 9, and the transfer pipe It is further provided with a filtration device (21) installed on the (22) to process the organic material contained in the treated water by the filtration method by the filter.

In addition, in the wastewater treatment system of the present invention, a coating agent dispensing apparatus 23 is further installed on the conveying pipe 22 path connecting the sludge treatment apparatus 9 and the filtration apparatus 21, and the filtration apparatus 21. It is characterized by supplying a coating to the treated water to be transferred to the coating to be coated on the filter to increase the removal efficiency of the organic material.

The first embodiment of the filtration device 21 is largely as shown in Figure 3a, the inlet guide member 24 and the drain guide member 25 for guiding the inflow and discharge of the treated water and the inlet guide member 24 and Sludge and organic matter contained in the primary treatment water passing through the cylinder 26 is installed inside the cylinder 26 having a cylinder 26, a hollow pipe-shaped body is fixed between the drain guide member 25 At least one filter 27 for filtering the material, and a fixing plate 28 through which the fixing hole 28a penetrates inside the drain guide member 25 and accommodates the filter 27 therein. Include.

The inlet guide member 24 has an inlet (24a) is formed so that the conveying pipe 22 connected to the sludge treatment apparatus (9) is formed, the portion connected to the cylinder 26 is opened to enter the inlet (24a) The treated water is configured to be transferred to the cylinder 26. In addition, the acquisition guide member 24 has a locking step 24b for fixing the lower portion of the cylinder 26 and the frame (F) on the side wall.

The acquisition guide member 24 configured as described above may be configured in various shapes. In the drawing, the cover 24c is fastened and fixed to the bolt B at the lower portion thereof and is detachably assembled. In addition, the acquisition guide member 24 may be configured in a container shape by integrally the cover (24c).

The drain guide member 25 is for guiding discharge of the treated water that has passed through the cylinder 26 to the outside, and the outlet 25a for opening the lower portion of the body into which the cylinder 26 is inserted and discharging the treated water to the side wall. ) Is formed, and a locking step (25b) for fixing the cylinder 26 and the upper portion of the frame (F) is formed on the lower side wall.

The drain guide member 25 configured as described above may be configured in an integrated container shape, and the cover 25c is detachably fastened by the bolt B on the upper portion as shown in the drawing to clean the inside when the cover 25c is cleaned. Can be configured to be easily separated, and in addition to this can be configured in various shapes.

The cylinder 26 is formed in a hollow shape with both sides penetrated, and both sides of the cylinder 26 are inserted into and fixed to respective openings of the inlet guide member 24 and the drain guide member 25.

The cylinder 26 configured as described above is preferably made of a transparent material so as to visually check the replacement timing of the filter 27 accommodated therein and the treatment process of the treated water.

The filter 27 has a hollow pipe shape in which one end is closed and the other end is opened, and the open outlet part is fixed to a fixing plate 28 provided inside the drain guide member 25.

The filter 27 is required to be rigidly configured so that the treated water is not compressed or deformed when passing through the cylinder 26 at a high pressure by the inflow pump 29. As shown in FIG. 5, the coil spring 27a is embedded and the filtering member 27b is wrapped around the coil spring 27a.

The coil spring 27a supports the filtration member 27b so as not to be compressed or deformed, and the filtration member 27b enclosed at the outside thereof filters and removes the fine sludge and the organic material contained in the treated water. The filtration member 27b uses a conventional filtration member 27b obtained by weaving a PPI material.

Since the filter 27 configured as described above forms a space inside the coil spring 27a, the treated water passing through the filtration member 27b flows into the space and is discharged into the opening.

The fixing plate 28 is for fixing the filter 27 and is fixed inside the drain guide member 25 on the upper portion of the cylinder 26. The fixing plate 28 is formed with a fixing hole (28a) for receiving and fixing the opening of the filter 27 in the plate-shaped body to fix the filter 27, the fixing holes 28a Is formed. The fixing hole of the fixing plate 28 serves as a passage through which the treated water passing through the filter 27 can be transferred to the drain guide member 25.

The fixing plate 28 configured as described above is assembled in a state where airtightness is maintained on the inner wall of the upper drain guide member 25 of the cylinder 26.

On the other hand, the second embodiment of the filtration device 21 according to the present invention is the water supply guide member 24, the drain guide member 25, the cylinder 26, the filter 27, the fixed plate used in the first embodiment And a plate 30 having a drain hole 30a formed thereon so as to pass through the secondary treated water filtered by the filter 27, and fixed to the fixing plate 28. And a vibration motor 31 installed at the rod 25 and fixed to the fixing plate 28 through the diaphragm 30 to generate vibration.

Here, when the filter 27 is backwashed and cleaned, the filter 27 installed on the fixed plate 28 vibrates while the rod R of the vibrating motor 31 reciprocates up and down, and the sludge adhered to the outside of the filter 27. It is characterized by shaking off.

Since the inlet guide member 24, the drain guide member 25, the cylinder 26, the filter 27, and the fixing plate 28 have been described in detail in the first embodiment, a detailed description thereof will be omitted.

However, the water supply guide member 24 is formed with an outlet 24d so that the washing water can be discharged to the raw water storage tank 2 when the filter 27 is backwashed, and the drainage guide member 25 may supply the washing water. The washing water supply pipe 32 is connected to the outlet 25a.

In addition, in the second embodiment, the fixing plate 28 is different from the first embodiment in that the reciprocating slide is installed in the drain guide member 25.

In addition, the diaphragm 30 is to allow the treated water filtered by the filter 27 to be discharged to the outside, for this purpose, a drain port 30a for guiding the discharge of the treated water to the plate-shaped body and a vibration motor at the center thereof. The guide hole 30b penetrates through the rod of 31. The diaphragm 30 configured as described above is positioned above the fixing plate 28 and fixed to the inner wall of the drain guide member 25.

The vibration motor 31 is for removing sludge or organic matter adsorbed on the filter 27 in a vibrating manner, which is installed outside the drain guide member 25, preferably mounted on the drain guide member 25. The rod R penetrates and is fixed to the fixed plate 28 through the guide hole 30b of the diaphragm 30, so that when the power is supplied, the rod R reciprocates at a high speed to open the fixed plate 28. When the filter 27 fixed to the fixed plate 28 vibrates, sludge or impurities adsorbed on the outer circumference thereof are removed.

In addition, the coating agent dispensing apparatus 23 installed in the conveying pipe 22 is a storage tank 23a for storing the coating agent, and a coating agent supply pump 23b for quantitatively supplying the supplied coating agent to the acquisition guide member 24. It is composed.

The coating agent is good to use the bedrock stone powder having excellent cohesion of suspended solids (SS) and good absorption of organic materials (BOD) (COD). Elvan stone powder is diluted with an appropriate concentration in dilution water supplied separately and supplied to the filter 27.

Accordingly, the coating material supply pipe 33 for supplying the coating material has one end connected to the coating storage tank 23a and the other end connected to the conveying pipe 22, and the coating material supply pump 23b on the path thereof. Is installed.

The coating agent is mixed with the primary treatment water supplied to the transfer pipe 22 by driving the coating supply pump 23b and coated on the filtration member 27b of the filter 27.

The coating agent supply pump 23b is determined by the controller when its operation time and driving time are supplied to quantitatively supply the coating agent.

The filtration device 21 of the second embodiment forms an outlet 24d at the water supply guide member 24 and connects a conveying pipe 34 between the outlet 24d and the raw water storage tank 2. When the washing water supply pipe 32 is connected to the outlet 25a and the conveying pipe 22 of the drainage guide member 25, the impurities attached to the filter 27 are shaken off using the vibration motor 31 ( Backwashing) The treated water conveyed through the conveying pipe 22 is introduced into the outlet 25a of the drain guide member 25 to expand the filter 27 while passing through the inside of the filter 27, thereby expanding the filter 27. It is characterized in that it is configured to help remove impurities blocking the voids, and the impurities removed in this process are fed back to the raw water storage tank 2 through the outlet 24d of the inlet guide member 24. .

In addition, the filtering device 21 of the first and second embodiments is provided with a diaphragm 35 so as to alleviate this vortex because the treated water supplied into the inlet guide member 24 flows into the vortex. The diaphragm 35 is formed with a through hole 35a to allow the treated water to be passed through.

Next, the wastewater treatment system of the present invention configured as described above will be described a process for treating wastewater.

Before starting the wastewater treatment system, first, the valve 23c is opened, the other valve 32a positioned below the valve 23c is shut off, and the coating supply pump 23b is driven to store the storage tank 23a. The coating agent diluted in this is supplied to the filtration member 27b of the filter 27 and coated. When the coating process is coated for about 5 to 10 minutes, the lamellar powder is coated in a state of being laminated on the surface of the filtration member 27b to form voids separately from the filtration member 27b.

Subsequently, when the wastewater treatment system is in full operation, the chemical treatment apparatus 6 and the sludge treatment apparatus 9 treat the wastewater as usual, and the sludge dehydrator 10 dehydrates and discharges it to the outside. The generated turbid treatment water is returned to the raw water storage tank (2).

Specifically, the wastewater stored in the raw water storage tank 2 is driven by the raw water transfer pump 3 to transfer to the stirrer 5 of the chemical treatment apparatus 6. At the same time, the chemical treatment apparatus 6 transfers the chemicals stored in the chemical tank 4 to the stirrer 5, and the stirrer 5 is a waste water supplied by rotating the propeller 5a by the power of the motor. The chemicals are mixed to form sludge.

At this time, the chemicals used are polymer, caustic soda, and ferrous sulfate, and these chemicals agglomerate foreign substances contained in the wastewater to form sludge.

The sludge thus formed is transferred to the sludge treatment apparatus 9 by the raw water transfer pump 3, and the sludge treatment apparatus 9 collects the sludge from the collection tank 7 and sends the sludge to the concentration tank 8. Is sent to the primary treated water storage tank 9a.

The sludge stored in the concentration tank 8 is dehydrated in the dehydrator 10 to be discharged to the outside, and the dehydrated and turbidly treated water is returned to the raw water storage tank 2 again.

When the valve connected to the sump tank 7 of the sludge treatment apparatus 9 is opened, the primary treatment water stored in the primary treatment water storage tank 9a is obtained by the inflow pump 29. It is supplied to the guide member 24 and is filtered by the filter 27 while passing through the cylinder 26. At this time, the treated water is pumped under high pressure by the inflow pump 29 and suspended matter and organic matter contained therein. After filtering by the coating agent and the filtration member (27b) is discharged to the outside by the power of the outflow pump (36).

At this time, the filter 27, the inner coil spring (27a) to withstand the high-pressure treated water, so that the filter 27 is not compressed or deformed.

In the process of filtering the waste water as described above, since the pores of the agglomerate powder coated on the filter 27 have many pores formed therein, the organic substances are absorbed and stored in the pores. Since the elvan powders are coated in close contact with each other, the suspended solids (SS) are filtered in the space formed between them.

When the wastewater is treated for a long time in this way and the organic material is filled in the pores inside the powder coating agent and thus no more organic material can be absorbed, the coating agent dispensing device 23 is driven to quantitatively supply the coating material on a regular basis. To be absorbed.

When the wastewater is continuously treated in this manner, the coating agent accumulates in the filtration member 27b of the filter 27 to block the pores of the filtration member 27b, and at the same time, the space between the elvan and the elvan powder is blocked. In this case, since the filtration function of the filter 27 is lost, the coating agent adsorbed on the filter 27 must be removed.

As described above, the process of removing the coating agent, in the case of the first embodiment, opens the cover 25c of the drain guide member 25, pulls out the filter 27 to the outside, and then shakes the filter 27 or vibrates by other means. Can be removed with

In the second embodiment, when power is supplied to the vibration motor 31, the rod R of the vibration motor 31 moves up and down at a high speed to vibrate the filter 27 to the filtration member 27b. Absorbed foreign matter and coatings can be removed. At this time, when the valve 33a installed on the conveying pipe 22 and the valve 23c provided on the coating material supply pipe 33 are locked and the valve 32a provided on the washing water supply pipe 32 is opened, the treated water is supplied to the washing water supply pipe. After the 32 is introduced into the drain guide member 25 and then introduced into the filter 27 to expand the filtration member 27b, foreign substances attached to the coating agent and the filtration member 27b can be removed cleanly. .

When cleaning the filter 27 as described above, if the coil spring 27a of the filter 27 is transmitted by the vibration of the vibration motor 31 itself because the elasticity of the vibration wavelength is irregular, the back washing effect To maximize.

In this way, the washing water, which has been cleaned by the backwashing method, is collected in the water supply guide member 24, and the washing water is collected through the conveying pipe 34 by driving the inflow pump 29. It is transferred to 2) and processed again.

Example 1

Industrial wastewater generated when dyeing the fabric was treated using the wastewater treatment system of the present invention, the results are shown in the following table.

Raw water Raw water average concentration After primary chemical treatment After Secondary Filter Treatment COD 500 ppm 100 ~ 200PPM 20-50 PPM BOD 400 PPM 100 ~ 150PPM 10-40 PPM SS 250 ppm 80 ~ 120PPM 0.1 to 1 PPM

In case of relying only on chemical treatment for industrial wastewater treatment, flocculation chemicals are used to agglomerate the particles and then solid-liquid separation in the sedimentation tank. It spills and eventually causes deterioration of treated water quality. In order to prevent this, sand filters, activated carbon filters and other expensive ultrafiltration membranes (separation membranes) are installed as secondary facilities. However, due to the difficulty of the installation process, the installation cost is high, and the maintenance costs are excessive, it is easy to become famous.

On the contrary, when the wastewater was treated using the wastewater treatment system of the present invention, the COD concentration of the wastewater was 500PPM before treatment, but was lowered to 100 to 200PPM after the first treatment with chemicals, and the secondary by the filtration device 21. After treatment, it was significantly lowered to 20 to 50 PPM.

In the case of BOD, it was 400 PPM before the treatment, but was lowered to 100 to 150 PPM after the first treatment with the chemical, and to 10 to 40 PPM after the second treatment by the filtration device 21.

In the case of SS, it was 250 PPM before treatment, but it was lowered to 80 to 120 PPM after the first treatment with chemicals, and as low as 0.1 to 1 PPM after the second treatment by the filtration device 21.

As a result of this treatment, it can be seen that COD is more than 90%, SS is more than 98%.

Example 2

The results of treatment of domestic wastewater or manure using the wastewater treatment system of the present invention are shown in the following table.

Raw water Raw water average concentration After biological treatment After filtration BOD 300 ppm 20 ~ 60PPM 10PPM or less SS 250 ppm 20 ~ 80PPM 0.1 to 1 PPM

Biological treatment (active sludge method) is commonly used for the treatment of existing wastewater, and the amount and concentration of sewage generated in the field is lower than the designed value, and sludge is fined due to peroxidation due to excessive microorganisms due to lack of sludge concentration facilities or insufficient capacity. In most cases, untreated sludge may be mixed into the effluent and cause the treated water to deteriorate. In response to this, sand and activated carbon separators (ultrafiltration membranes), etc., have been installed, but are difficult to install and operate due to difficult maintenance and high installation and maintenance costs.

On the contrary, as a result of treating wastewater or manure using the wastewater treatment system of the present invention, the BOD concentration of the wastewater was 300PPM before treatment but was lowered to 20 to 60PPM after the biological treatment, and after the second treatment by the filtration device 21. Significantly lowered below 10PPM.

The suspended solids (SS) was 250 PPM before treatment but lowered to 20 to 80 PPM after biological treatment and to 0.1 to 1 PPM after secondary treatment by filtration device 21.

As a result of this treatment, it can be seen that the BOD is processed more than 80%, SS is more than 98%.

The wastewater treatment system of the present invention configured as described above can further increase the efficiency of wastewater treatment by further installing a filtration device in a conventionally installed wastewater treatment system, as well as solid-liquid separation tank, sand filtration tank, activated carbon filtration tank and water recycling in response to environmental regulations. As an alternative to secondary and tertiary facilities, it is possible to secure a stable water treatment system and to reduce installation and operating costs.

In addition, since the filter can be backwashed and reused under high pressure, it is not necessary to change the filter frequently, thus reducing the cost and time wasted due to the filter change.The filter has a built-in coil spring that makes the vibration irregular, so the filter is backwashed. It has the advantage of increasing the effect.

Claims (7)

Raw water storage tank (2), the raw water transfer pump (3) for transferring the waste water stored in the raw water storage tank (2) to the outside, each provided with a chemical tank (4) and the raw water storage tank (2) each agitator (5) ) And a sludge conveyed from the chemical treatment apparatus (6) to mix the wastewater and the chemicals supplied from each of these tanks in the stirrer (5) to form sludge. In the wastewater treatment system consisting of a sludge treatment apparatus (9) for storing in the c), a dehydrator (10) for dewatering and discharging the sludge stored in the concentration tank (8) and transfer the treated water back to the raw water storage tank (2). , A separate conveying pipe 22 is connected to the primary treated water storage tank 9a of the sludge treatment apparatus 9, and the conveying pipe 22 contains suspended solids and organic matter contained in the treated water by filtration by a filter. Installing a filtration device 21 for processing the material, the filtration device 21, the inlet guide member 24 having an inlet; A drain guide member 25 having an outlet; A cylinder 26 having both sides penetrated therein and connected to both sides of the inlet guide member 24 and the drain guide member 25 to be in communication with each other; At least one filter 27 having a hollow pipe-shaped body having an open end at one end thereof, and installed in the cylinder 26 to filter sludge and organic substances contained in the treated water passing through the cylinder 26; And a fixed plate (28) accommodated in the drain guide member (25) to be liftable and fixed to the opening of the filter (27). The coating agent dispensing apparatus 23 is further provided on the conveying pipe 22 path connecting the sludge treatment apparatus 9 and the filtration apparatus 21. Waste water treatment system characterized in that to coat. delete delete delete 2. The filter of claim 1, wherein the filter (27) comprises: a coil spring (27a); And a filtering member (27b) wrapped outside the coil spring (27a). delete