KR100314752B1 - Solid/liquid separator for septic tank - Google Patents

Abstract

PURPOSE: Provided is a solid/liquid separator for septic tank, which is characterized in that a screen is washed by air bubble. Therefore clogging of screen is prevented, and high concentrated wastewater is treated continuously. CONSTITUTION: The apparatus includes a solid/liquid separator(1) installed in a septic tank, composed of an inner screen(5) and an outer screen(6); and an air bubble pipe(7) installed at the lower part of the outer screen(6). The screens(5,6) are inclined at the degree of 2-10. Mesh size of screens is 0.5-10 mm. Therefore, maintenance of screens is easy, and solid/liquid separation is operated continuously.

Description

Solid-liquid separator

The present invention is mainly used in sewage treatment facilities, pre-treatment of high concentration sewage, such as manure, mixed wastewater, industrial drainage, and solid solution for separating and removing solid components from sewage containing fine solid components in the granular phase It relates to a separation device.

Conventionally, in a septic tank which merges household sewage and manure, when the septic tank is small, the effect of solid-liquid separation is inadequate due to solid-liquid separation by sedimenting solids of sewage and manure. And in the medium and large-scale general sewage treatment facilities with more than 101 people, do not install coarse bar screens of 50 mm thick, screening devices, fine screens 20 mm thick and fine wood screens 2 mm thick for pretreatment. If it was not.

The pretreatment apparatus in such a medium and large septic tank had the following problems.

1) Existing screens with large nets are installed in the form of bar screens of 50 mm intervals in the waterway, or in the form of automatic screening, in which case dirt is deposited and clogged eyes, or automatic type Since the filth is filtered and mixed, it is a cause of odor pollution and sanitary pests.

2) Even in the case of installing a fine screen, the existing screen is designed to filter out dirt, and thus, as in the screen of a large mesh, the filtered dirt causes pollution. Since the mesh is a 20mm bar screen, hair and other fibrous materials, such as hair, may pass directly through the mesh, causing the accident to be wound around the rear end of the pump.

3) Even in the case of installing the detail screen, the pollution is generated from the filtered waste as in the case of the large screen or the detail screen, and it is unsanitary. Recently, the membrane separation method is being adopted in the midst of the advancement of advanced treatment facilities to enhance the purification effect from the point of view of environmental preservation. It is a fact that most of these things are passed through and an accident that is entangled in the membrane occurs. In addition, while being automated with high processing, something like hair modeling is entangled in the sensor, causing malfunction.

In the present invention, in the treatment of all sewage, the pretreatment is processed by using a required screen, but bubbles are raised in the water in which the screen is installed, and the rising bubbles wash the screen and the eyes of the screen By preventing clogging, it is possible to solidify high concentration sewage in a continuous way to solve the above problems at once, reduce construction costs, facilitate maintenance and reduce operation and maintenance costs. The purpose is to provide a device.

By pretreatment of all sewage with this solid-liquid separation device, it is possible to exert an innumerable good effect in terms of economics, hygiene, or environmental preservation compared to the conventional pretreatment.

1 is a cross-sectional view of the main portion of the solid-liquid separator of the present invention

2 is a cross-sectional view of the solid-liquid separator in the embodiment shown in FIG.

Figure 3 is a partial cross-sectional view of another embodiment of the present invention configured differently the structure of the solid-liquid separator

Figure 4 is a sectional view of the main portion of another embodiment of the present invention with a measuring container

<Description of the code | symbol about the principal part of drawing>

1. Solid-liquid separator 2. Base 4. Top plate

5. Inner Screen 5a. Metal mesh 5b. Resin film

6. Outer screen 7. Air ejection pipe 8. Filtrate suction pump

9. Separator 9a. Taper part

10a. Transfer line 10b. Discharge pump

11.Sewage inflow pipe 12.Air supply pipe

13. Filtrate suction tube 14. Transfer tube

15a.Blower

16. Pretreatment device 16a. Pretreatment tank 16b. Pretreatment screen

16c.Air supply line 16d.Air supply line 16e.Outlet line

20. Air lift pump

20a.Inner tube 20b.External 20c.Air delivery pipe

30.bubble

31.Solids

32.Fiber Bundle

The present invention for solving the above problems, the box-shaped solid-liquid separator 1 formed at least one surface of the outer periphery (screen) is disposed under the water surface of the water tank in which filthy water flows, the outer bottom of the screen A bubble generator is installed to allow bubbles to rise along the screen, and a conveying pipe is installed to pass the sewage out through the screen into the box-type solid-liquid separator 1 to the outside, and the screen is turned toward the bubble direction outward. As described above, it is characterized by the fact that the rising bubbles by washing the screen to prevent the clogging of the screen, and the lumps in the sewage aggregates as the sewage is circulated to facilitate the treatment of the lumps.

In the present invention, the sewage in the water tank flows toward the conveying pipe provided in the solid-liquid separator 1. Since at least one side of the solid-liquid separator 1 is provided with a screen having a mesh size required on at least one side of the outer circumference, sewage is filtered by the screen. That is, solids, dirt, etc. larger than the mesh size of the screen do not flow to the inside of the screen but stay on the outside. In the present invention, the bubble generator is provided to generate bubbles in the lower side of the screen. Remnants and SS (suspension substances) that can get stuck on the screen are pushed upwards by bubbles to prevent screen clogging. Moreover, since the solids and SS larger than the size of the mesh of the screen staying on the outside rather than flowing inside by the screen are pushed upwards, the function of the screen is not impaired. In addition, since the bubbles touch the solids temporarily staying outside the screen, they are brought into contact with the screen at the time of ascending, miniaturizing and solubilizing, and the treatment efficiency is increased.

By installing the air lift pump inside the solid-liquid separator 1, it is possible to reduce the blockage by transporting the liquid by bubbles generated in the lower portion.

Multiple screens and bubble generators are provided in multiple stages so that filthy water can be filtered out multiple times, and the screen is filtered through a screen with a smaller mesh size while preventing screen clogging due to air bubbles. It is possible to treat the sewage highly.

By placing the solid-liquid separator 1 in the center of the tank to cause swirl flow in the sewage in the tank, the solids, SS, and residues that have not passed through the screen by bubbles outside the screen are moved by the swirl flow. The heavier ones settled and the lighter ones stayed in the center of the slow-flowing swirl flow and did not stagnate near the screen, so that the filtration function of the screen was not impaired.

The inner screen 5 is formed by attaching a resin film having a mesh of fine pores to the metal mesh having a large mesh, and having a mesh made of pores on the outside of the inner screen 5 configured as described above. By arranging a plurality of second screens and outer screens 6 such as third and fourth, filtration is performed by pores while preventing meshes such as second screens from being blocked by bubbles, followed by bubbles. While the screen is not clogged, the resin is filtered by a resin film having a smaller mesh size so that the sewage is treated highly.

The inclination of the inner and outer screens and the pretreatment screens to 2 to 10 degrees outwards removes debris from the screen, which tries to entangle the screen as bubbles rise along the screen so that the net is not blocked.

By providing a discharge device for discharging accumulated sediment at the bottom of the tank, the sediment was discharged to the outside for use as compost.

By installing the measuring vessel above the surface of the water and installing the discharge pipe and the reflux tube, the sewage discharged from the inside of the solid-liquid separator 1 temporarily stays in the measuring container, so that the sewage of a predetermined amount or more is transferred to the tank through the reflux tube. By returning to the inside, the sewage in the measuring container is kept at a certain level, and the wastewater maintained at the predetermined level is discharged to the outside through the metering pipe, so that the sewage in the tank can be stably discharged.

By installing the pretreatment device, large wastes and debris were removed by the pretreatment screen, and the sewage passing through the pretreatment screen was discharged into the lower tank, so that sludge and the like in the sewage settled quickly.

By forming a pretreatment screen with a perforated plate of 0.5 to 10 mm in diameter, trash or debris larger than the size suitable for treatment with the screen in the tank was removed to allow efficient filtration by the screen in the tank.

It consists of a sewage purification tank equipped with an anaerobic tank and an aerobic tank at the rear of the solid-liquid separator, and discharges the wastewater treated by the solid-liquid separator by biochemical treatment. It was made to be water without problems. The sewage sent to the anaerobic tank or the aerobic tank is treated at high altitude with a solid-liquid separator, so that the solids in the sewage can be finely processed so that all solids can be processed quickly and sufficiently.

As the screen, a metal plate having a large number of holes having a predetermined size formed in the metal plate, a synthetic fiber fabric, a plate body punched by punching, a mesh of steel wire, etc. may be used. It is necessary to have a mesh with a size that meets the purpose.

The solid-liquid separator 1 may have any shape, such as cylindrical shape, triangular column shape, or polygonal column shape.

The solid-liquid separation device may be provided with a separate processing device at its front or rear end according to its purpose and use.

An apparatus for transferring the filtered sewage to the screen includes a pressurized pump or an air lift pump.

The opening ratio of the pretreatment screen is preferably 40 to 60%, and the diameter of the hole is preferably 0.5 to 10 mm.

When described with reference to the accompanying drawings an embodiment of the present invention as follows.

Example 1.

1 to 2 are related to a sewage purification tank of a livestock farm, and are installed at the front end of the anaerobic tank and the aerobic tank, and the solid-liquid separator 1 is installed at the center of the tank into which the sewage flows. In order to cause the flow of sewage in the sewage, and to install a plurality of screens on the outside of the solid-liquid separator 1 so that the sewage can be filtered multiple times, the inner screen has a mesh diameter of 5 mm. A resin film having a diameter of 20 μm was attached to the phosphorus metal plate, and the outer screen was made of a metal mesh plate having square holes having a mesh width of 2 mm. Bubbles are generated on the outside of each screen by a bubble generating device, and as a pretreatment device, a pretreatment tank is connected to an inlet through which sewage flows into the tank, and the pretreatment tank is partitioned with a pretreatment screen. A bubble generator is installed at the lower side of the inlet side of the pretreatment screen to generate bubbles, and a discharge pipe for discharging the filtered sewage downward is provided at the lower part of the pretreatment tank. It is an example of the solid-liquid separator which provided many discharge apparatuses, and provided the discharge apparatus which discharges a deposit.

Example 1 shows a sewage treatment facility equipped with a solid-liquid separator for manure treatment of livestock farms in the Shimako district of Nagasaki Prefecture. For the final treatment of sewage treatment facilities, a filtration device that filters filtration through a hollow fiber membrane having a mesh of 0.1 μm is installed, and the sewage is treated with aerobic bacteria in front of it, 2 m long by 3 m wide by 2 m high. An anaerobic tank (not shown) and an anaerobic tank (not shown in the figure) 2 m in height x 5 m in width and 2 m in height are treated to treat sewage with anaerobic bacteria, and the sewage cycles between the aerobic and anaerobic tanks as necessary. A circulation system was installed so that a separation tank 9 having a length of 2 m x 2 m x 2 m in height was installed at the front of the aerobic and anaerobic tanks. The lower part of the separation tank 9 is provided with a tapered portion 9a so that sediment or sludge can be collected at the center of the bottom surface of the separation tank 9. A sewage inflow pipe 11 for introducing sewage into the separation tank 9 was installed in the upper portion of the separation tank 9. The discharge pipe 10 of the discharge device for discharging sediment or sludge accumulated in the lower part of the separation tank 9 to the outside was installed at approximately the center of the lower part of the separation tank 9. The pretreatment apparatus 16 was installed in the separation tank 9. As shown in Fig. 1, the pretreatment device 16 includes a pretreatment tank 16a provided with an inlet of the sewage inflow pipe 11 for discharging sewage into a separation tank, and the pretreatment tank 16a. It consists of a pretreatment screen 16b which is divided and partitioned, and the pretreatment screen 16b is installed at an inflow side of the sewage and inclined about 5 degrees toward the bubble generation. The pretreatment screen 16b is made of a metal mesh board of square holes having an eye width of 5 mm. The air injection pipe 16c is provided in the inflow side below the pretreatment screen 16b. The air injection pipe 16c is provided with many holes for blowing bubbles. An air supply pipe 61d equipped with a blower is attached to the air injection pipe 16c. A hole was made in the bottom surface of the outflow side of the pretreatment tank 16a partitioned by the pretreatment screen 16b, and the discharge pipe 16e was attached to the hole.

In the separation tank 9, a solid-liquid separation device 1, as shown in Figs. 2 and 3, was installed. The solid-liquid separation device 1 has two sides facing the base 2, as shown in Fig. 4. It consists of an inner screen (5) installed in, an outer screen (6) installed on the outside of the inner screen (5), and a side plate and a top plate (4) that block the side and upper surfaces of the inner screen (5). The inner screen 5 was formed by attaching a metal mesh plate 5a made of a square hole having an eye width of 5 mm and a resin film 5 b having an eye width of 20 μm. In addition, each inner screen 5 is provided with the outer end inclined at about 5 degrees. The outer screen 6 provided on the outside of the inner screen 5 also has the same shape as the inner screen 5, and its upper end is inclined at about 5 degrees. The outer screen 6 is formed of a metal mesh with a square hole of 2 mm in eye width. The filtration area of the inner screen 5 and the outer screen 6 is 0.5 m 2. An air blowing pipe 7 was provided near the outer lower end of each of the screens 5 and 6. The air blowing pipe 7 is provided with many blowing holes for blowing bubbles. An air supply pipe 12 is connected to the air ejection pipe 7, and is connected to the air supply pipe 16d of the pretreatment device 16 to be connected to the air supply pipe 12. Therefore, the air supply pipe 12 of the solid-liquid separator 1 ejects air by the same blower 15a together with the air supply pipe 16d.

The suction port of the filtrate suction pipe 13 is provided so as to be located between the two inner screens 5. The side plate is provided in the side in which the inner screen 5 is not provided in the side of the base 2, and the side end of the inner screen 5 and the side plate contact each other tightly, and it is watertight. It is supposed to have (水密 性). In addition, a top plate 4 is provided above the space surrounded by the inner screen 5 and the side plates. The top plate 4 is provided to have a watertightness in contact with the top of the side plate and the top of the inner screen 5 without gaps. A filtrate suction pump 8 is provided on the side opposite to the suction port of the filtrate suction tube 13. At the outlet of the filtrate suction pump 8, a transfer pipe 14 for post-stage treatment is provided. Hereinafter, the filtrate suction pipe 13 and the transfer pipe 14 are referred to as transfer pipes.

In the first embodiment, the solid-liquid separator 1, the screen, and the bubble generating device are constituted as one unit, so that miniaturization is possible and it is possible to install in an existing tank. In addition, since the position in the tank can be freely changed, it is not necessary to separately provide one for each tank according to the tank, thereby reducing the cost.

The farmer raises 1,000 pigs, 100 of which are pigs. The pigs are treated separately, but 8,000 liters of urine are discharged per day. The discharged urine water is sent to the separation tank 9 of the sewage treatment facility by the sewage inflow pipe. The SS (suspension substances) of the introduced sewage was 2700 mg / liter and the dissolved oxygen consumed by aerobic microorganisms was 15,000 mg / liter. This wastewater is sent to the inside of the pretreatment tank 16a of the pretreatment apparatus 16 by the wastewater inflow pipe 11 as shown in FIG. Since the pretreatment tank 16a is provided with a pretreatment screen 16b as partitioning, the sewage flows so that both sides divided by the pretreatment screen 16b are at the same water level. 5 mm square holes pass through the pretreatment screen 16b. Due to this, sewage is filtered, so that coarse material such as hair or straw does not pass through the pretreatment screen 16b. These substances are removed regularly. The pretreatment screen 16b is inclined about 5 degrees to the inflow side of the sewage, and is cleaned by the rising bubble ejected by the air injection pipe 16c located near the lower end of the pretreatment screen 16b, and the air injection pipe 16c. The rising bubbles blown out by the air generate swirl flow in the sewage of the pretreatment tank 16a. Hairs or straws that do not pass through the pretreatment screen 16b due to the generated swirl flow are raised by rising bubbles, and thus the pretreatment screen 16c cannot be blocked. In addition, the article dissolves as the bubbles come into contact with each other and the finer than the mesh of the pretreatment screen 16b passes through the pretreatment screen 16b. In addition, the pretreatment screen 16b is inclined to the inflow side by about 5 degrees so as not to force the straw or the like to pass through. Heavy sediment or sludge in the sewage passing through the pretreatment screen 16b is settled downward through the discharge pipe 16e, and moves to the bottom of the separation tank 9. At this time, since the taper part 9a is provided below the separation tank 9, sediment or sludge collects in the center part of the bottom face of the separation tank 9.

Filtration with suction inlet in the space surrounded by the inner screen 5 and the side plate, the top plate 4 and the base 2 of the solid-liquid separator 1 located in the center of the separation tank 9 as shown in FIG. By operating the filtrate suction pump 8 connected to the liquid suction pipe 13, the sewage is sucked into the inner screen 5, so that a pressure difference occurs in and out of the outer screen 6, and the sewage outside the outer screen 6. Try to flow inward. For this reason, the wastewater of the separation tank 9 flows toward the screen part of the solid-liquid separator 1. The air ejection pipe 7 provided below the outer screen 6 of the solid-liquid separator 1 and the air ejection pipe 7 provided below the inner screen 5 are directed toward the oblique upper side of each screen. As shown in 1 and 2, bubbles are blown out. For this reason, the wastewater of the vicinity of the side surface of the both sides of the solid-liquid separator 1 located in the center of the separation tank 9 rises, and the wastewater near the wall surface of the separation tank 9 falls, and a swirl flow arises. When the sewage flows toward the outer screen 6, the outer screen 6 is formed of a metal mesh board formed with a large number of square holes having a net width of 2 mm, so that the solid 31 larger than this opening portion opens the outer screen 6. It does not pass and flows upward by bubbles. Thus, clogging of the screen does not occur by moving the solid material which has not passed through the screen in order upwards. Solids that are blown up by bubbles and flowed out by convection are solubilized or crushed so that they become smaller than the mesh of the outer screen 6. Move towards 5). Since the inner screen 5 is formed by attaching a resin film having a mesh width of 20 µm to a metal mesh board having a large number of square holes having a manganese width of 5 mm, the solid material 31 larger than this hole even if passed through the outer screen 6 has an inner screen. It will flow upward by bubbles without passing through (5).

The solid 31 encounters bubbles, flows by convection, undergoes resistance with water, and again undergoes crushing due to miniaturization or solubilization, so that the solid 31 becomes smaller than the mesh of the inner screen 5, and the smaller solid 31 Again passes through the outer screen 6 and the inner screen 5 to reach a space surrounded by the inner screen 5, the side plate, the top plate 4 and the base 2. The sewage containing the fine solids reached in this space is sucked by the filtrate suction pump 8 through the filtrate suction tube 13, and is passed through the transfer tube 14 to the post-treatment apparatus. SS of filthy water filtered by the solid-liquid separator of 270mg / liter is 90% removed. In addition, BOD is 4,500mg / liter, which is 70% removed. As such, the present invention allows to perform a very high degree of sewage pretreatment. Thereafter, biochemical treatment is performed by anaerobic and aerobic tanks, and finally, the filtration is performed with a hollow fiber membrane having a mesh of 0.1 µm. Since the advanced pretreatment has already been carried out in the solid-liquid separator, even if the mesh of the hollow fiber membrane is made as fine as this, the mesh is not blocked and the function is not impaired immediately. In this way, the treated water finally discharged has an SS of 3 mg / liter or less and a BOD of 10 mg / liter or less. As described above, in the solid-liquid separator of the first embodiment, the action of air bubbles on the inlet side of the screen prevents clogging of the mesh and reduces the need for maintenance, thereby reducing the failure of the pump due to entanglement of debris or dirt. You can. In addition, sediments and sludge accumulated on the bottom of the separation tank 9 are transferred to the discharge tank 10b and the compost to the discharge pump 10b through the transfer pipe 10a, if necessary, to be pumped or drained. Scatter on the field. However, because the removal of urine proceeded, the smell is not so great.

Example 2.

3 and 4 show that the air lift pump is installed in the transfer pipe to discharge the sewage filtered through the screen to the outside, and the screen is installed on only one side of the outer periphery of the solid-liquid separator 1. Yes.

In Example 2, the improved structure of the filtrate suction pipe which directs the filtered wastewater by the air lift pump 20 to the process apparatus of a later stage is shown. As shown in FIG. 3, the air lift pump 20 extends downward from the solid-liquid separator 1, and has an exterior 20b with a closed lower end and an inner tube 20a provided inside the exterior 20b. And an air delivery pipe 20c installed inside the inner pipe 20a. The inner tube 20a extends to the upper side of the separation tank 9, and the transfer pipe 14 to the post-stage treatment apparatus is coupled to the upper end. The sewage, which is filtered by the inner and outer screens 5 and 6 and located inside the solid-liquid separator 1, moves downwardly from the opening of the exterior 20b by hydraulic pressure to fill the interior of the inner tube 20a to the surface of the water. In this state, when the air is ejected from the lower end of the lift air delivery pipe 20c, the sewage inside the inner pipe 20a is moved upward by the upward force of the air. In this way, the sewage in the solid-liquid separator 1 is continuously sent upward, and is sent to the after-treatment apparatus by the conveying pipe 14. Since the air lift pump 20 is not provided with a screw or the like, there is no fear of trouble due to tangling of dirt and it is convenient to use. In addition, in the solid-liquid separator 1 of the second embodiment, the screen is installed only on one side and the solid-liquid separator 1 can be installed near the side wall of the separation tank 9. Since the position where the solid-liquid separator 1 is to be installed must be determined by the condition of the separation tank and the relationship with other devices, the solid-liquid separator 1 can be installed near the side wall of the solid-liquid separator 1. It may be desirable to.

Example 3

4 is a further improved structure of the filtrate suction tube, in which a metering container 24 is provided above the water surface to temporarily hold the sewage discharged from the solid-liquid separator 1, and a metering container. A metered discharge pipe 25 is installed at 24 to discharge a predetermined amount of sewage from the weighing container to the outside, and when the wastewater flowing into the weighing container 24 exceeds a predetermined amount, the excess water is separated into a separation tank ( 9) to provide a reflux tube 23 for reflux into the inside, and to send air through the air discharge pipe (20c) to discharge the sewage in the solid-liquid separator (1) to the outside.

The outer surface 20b of the air lift pump 20 extends upward to constitute a reflux tube 23, the upper end of the reflux tube 23 is opened, and an upper end of the open reflux tube 23 is a metering discharge tube ( 25) so that the sewage was filled from the metering vessel 24 to the top of the reflux tube (23). When air is sent to the air delivery pipe 20c of the air lift pump 20 in this state, the wastewater flowing out from the solid-liquid separator 1 rises with the air and flows into the metering vessel 24 through the air outlet 26. Comes out. In this way, when the sewage is accumulated in the measuring container 24 and the water level is higher than the upper opening of the reflux tube 23, the sewage flows into the reflux tube 23 and is returned to the separation tank 9. If the amount of air sent to the metering vessel 24 by the air pump is larger than the amount sent to the post-stage treatment by the metering pipe 25, sewage of a certain level in the metering vessel 24 regardless of the water level in the separating tank 9 It is always high and a certain amount of sewage is sent stably to the aftertreatment unit. In this way, the wastewater does not overflow or become too small in the after-treatment tank, and the treatment is stably performed.

According to the present invention, it is possible to carry out solid-liquid separation without clogging the mesh, to reduce the failure of the pump due to tangling of dirt, the filter agent does not cause clogging of the mesh, and thus maintenance work Has the effect of reducing In addition, the present invention can be installed in the water tank already installed and used, the cost is low, even if the manure of the livestock scattered in the field, such as less odor, and enables high filtration treatment at the rear end.

The present invention has the following effects as well as the above effects.

By installing an air lift pump inside the solid-liquid separator (1), it is possible to make a solid-liquid separator that can reduce the trouble and reduce maintenance work.

The screen and bubble generator are provided in multiple stages so that the sewage can be filtered many times, and the highly filtered sewage can be sent to the rear stage, thereby increasing the effectiveness of the post-treatment and reducing the size of the treatment facility. Have

By installing the solid-liquid separator 1 in the center of the separation tank to cause a swirl flow in the sewage in the separation tank has the effect of improving the treatment efficiency of sewage.

The inner screen is formed by attaching a resin film having a mesh of fine pores to a metal mesh board of large meshes, and the second screen is made of a metal mesh board of small meshes on the outside of the inner screen. It was sent to the rear end to increase the efficiency of the post-treatment and to make the treatment facility small.

By installing the screen and the pretreatment screen at an angle of 2 to 10 degrees as if falling down into the bubble, it is possible to reduce the maintenance work by preventing the screen from being clogged, and to have the effect of removing solids more than a predetermined size. It was.

By providing a discharge device for discharging accumulated sediment at the bottom of the tank, the sludge can be efficiently taken out and used as compost.

By installing the measuring container above the water surface and providing the metering discharge pipe and the reflux pipe, the sewage after the treatment can be stably discharged to the rear end so that the post-stage treatment can be performed stably.

By providing a pretreatment device, it is possible to further increase the treatment efficiency of sewage.

By using a porous plate having an ankle having a diameter of 0.5 to 10 mm as a pretreatment screen, it was possible to further improve the treatment efficiency of sewage.

By providing an anaerobic tank and an aerobic tank at the rear of the solid-liquid separator, the sewage purification tank removes nitrogen and phosphorus so that sewage can be efficiently treated and a wastewater purification tank can be provided to reduce costs.

Claims (8)

A solid-liquid separator 1 having at least one surface of the outer periphery formed as a screen is installed under the water surface of a water tank, and a bubble generator is installed below the outer surface of the screen to cause bubbles to rise along the screen. Solid-liquid separation, characterized in that the transfer pipe for discharging the sewage introduced into the solid-liquid separator 1 through the outside to the outside is installed inside the solid-liquid separator 1, and the screen is inclined 2 to 10 degrees outward. Device. The solid-liquid separation device according to claim 1, wherein the transfer pipe is provided with an air lift pump. The solid-liquid separation device according to claim 1 or 2, wherein the screen and the bubble generator are provided in multiple and multi-stages so that the sewage can be repeatedly filtered. The screen of claim 1, wherein the screen is formed by attaching a resin film having a fine mesh to a metal mesh having a large mesh, and a metal mesh having a larger mesh than the fine mesh formed in the above-described resin film outside the inner screen. Solid-liquid separation device, characterized in that consisting of the outer screen. The metering container according to claim 1, further comprising: a metering vessel for temporarily retaining the wastewater discharged from the solid-liquid separator 1; A reflux tube is installed to return the sewage above the predetermined amount into the tank, so that even if the amount of sewage in the tank is changed, the metering container maintains a certain level so that a predetermined amount of sewage can be stably sent to the outside. Separator. The pretreatment tank is provided at an inlet through which wastewater flows into the tank, and the inside of the pretreatment tank is partitioned with a pretreatment screen, and bubbles are generated at the bottom of the pretreatment screen to raise bubbles along the pretreatment screen. Solid-liquid separator by installing bubble generator and discharging pipe to send sewage through the pre-treatment screen into the lower tank. The solid-liquid separator of claim 6, wherein the pretreatment screen is a porous plate having a diameter of 0.5 to 10 mm. 8. The solid-liquid separation device according to claim 6 or 7, wherein the pretreatment screen is installed at an inclination of 2 to 10 degrees so as to fall toward the bubble.