CN113856336A

CN113856336A - Vacuum sewage discharging device capable of automatically separating gas, liquid and pollutants therein

Info

Publication number: CN113856336A
Application number: CN202111144708.0A
Authority: CN
Inventors: 徐宝贵
Original assignee: Fulaibao Paper Technology Shanghai Co ltd
Current assignee: Fulaibao Paper Technology Shanghai Co ltd
Priority date: 2021-09-28
Filing date: 2021-09-28
Publication date: 2021-12-31

Abstract

The invention discloses a vacuum sewage discharge device for automatically separating gas, liquid and pollutants in the gas and liquid. The device passes through many input pipelines of flashboard case control, makes the gas-liquid mixture of arbitrary input port all cut into cyclone at the minimum entry, and cyclone combines vacuum fan produces the high vacuum and carries out high-speed ground gas-liquid separation, will effectively with the pollutant (such as stickies) and the gas that contain in liquid with the fastest speed separation and flow into sealed basin fast, has solved the problem that pollutant (stickies or other impurity) in the liquid in the processing procedure easily dewater and solidify and condense at the separator inner wall.

Description

Vacuum sewage discharging device capable of automatically separating gas, liquid and pollutants therein

Technical Field

The invention relates to the technical field of separating devices, in particular to a vacuum pollution discharge device for automatically separating gas, liquid and pollutants (such as sticky matters and other impurities) in the gas and the liquid.

Background

At present, automatic separation devices for gas, liquid and pollutants in the gas and the liquid are mainly used for automatically separating oil water and/or a mixture of solid impurities and water. For the separation treatment of dirt such as stickies, especially for the vapor-liquid (including impurities, such as stickies) mixture entering the separator from the upper input port, the separation difficulty is relatively large, and the separation effect is not good.

The separator usually has a plurality of input ports, and is general, when the separator that imports more separates, the stickers bond at the inner wall surface after dehydrating very easily, can make impurity such as pollutant or stickers bond at the inner wall, when deposit volume is too big, can be the cubic pollutant and drop, and the cubic pollutant that drops like this very easily is inhaled vacuum blower and leads to vacuum blower damage, friction or catch fire.

In actual work, the inner wall of the separator is mostly cleaned by adopting a clean water washing mode after the work is stopped, the sewage is not treated timely, deposited pollutants are easy to dehydrate and then are solidified and condensed into blocks, and the blocks are sucked into the fan to damage the fan. Therefore, the prior art is difficult to meet the requirements of quick and efficient separation treatment and self-cleaning of gas, liquid and pollutants (such as stickies and other impurities) in the gas and the liquid.

Disclosure of Invention

The invention provides a vacuum sewage discharge device for automatically separating gas and liquid and pollutants (such as adhesive and other impurities) in the gas and liquid so as to meet the defects in the prior art.

The technical scheme provided by the invention is as follows:

a vacuum sewage draining device capable of automatically separating gas, liquid and pollutants in the gas and liquid comprises a gate plate control box, a cyclone separator, a sealed sewage draining groove and a vacuum fan, wherein the sealed sewage draining groove is positioned below the cyclone separator.

Preferably, the contaminant is or at least includes a contaminant such as stickies.

The gate plate control box comprises a dirt suction pipe and a gate plate valve for controlling the communication state of the dirt suction pipe; the cyclone separator comprises a shell, the bottom of the shell is provided with a drain outlet, the drain outlet is communicated with the sealed sewage drainage groove, the shell is provided with an air extraction opening, and the air extraction opening is communicated with an air inlet of the vacuum fan; the gas-liquid mixture dirt suction pipe is communicated with an inlet of the cyclone separator through a transparent window pipeline, and the inlet of the dirt suction pipe is cut into the bottom of the cyclone separator; the sealed sewage draining tank comprises a boiling ring, a sewage draining valve, a sewage draining pipe and an air blowing valve, wherein the side wall of the cylinder body of the sealed sewage draining tank is provided with an opening and communicated with the sewage draining pipe; the vacuum fan comprises a machine body, and the machine body is connected with a vacuum fan exhaust pipe and a vacuum fan air outlet pipeline.

Preferably, according to the requirement of separation speed, the included angle alpha between the inlet central line of the dirt suction pipe and the inner side of the cyclone separator is not more than 90 degrees, more preferably is adjustable within the range of 0-90 degrees, and the included angle beta with the horizontal line is more than or equal to 0 and less than 45 degrees.

In a preferred embodiment, the dirt suction pipe is provided with at least three groups or more, and the on-off operation of one or more of the groups is controlled by the gate valve.

In a preferred embodiment, a cylinder and an electromagnetic valve are further arranged in the gate plate control box and used for controlling the communication state of the gate plate valve.

In a preferred embodiment, the cyclone separator is also provided with three groups of self-cleaning valves which are respectively positioned at the left side, the right side and the upper part of the top cylinder cover of the cylinder body of the cyclone separator.

In a preferred embodiment, the cleaning pipeline at the upper part of the cyclone separator is used for cleaning the area which is easy to accumulate slag and is arranged at the joint part of the cutting opening and the wall of the separator cylinder.

In a preferred embodiment, a transparent window is further arranged in the middle of the sewage inlet pipeline communicated with the sewage suction pipe of the cyclone separator, and more preferably, the transparent window is communicated with the inlet of the cyclone separator and the sewage inlet pipeline through a connecting flange.

In a preferred embodiment, the top of the sealed sewage draining tank is provided with an opening which is communicated with the sewage outlet of the cyclone separator through a section of hollow pipe.

In a preferred embodiment, the sealed sewage draining tank comprises a sealed sewage draining tank cylinder, a boiling ring, an air blowing valve, a sewage draining valve and a sewage draining pipe; the device comprises a sealed sewage draining tank barrel, a blow-off valve, a blow-off pipe, a blow-off valve and a control valve, wherein the blow-off pipe and the blow-off valve are positioned outside the sealed sewage draining tank barrel, a first pipeline hole is formed in the side wall of the sealed sewage draining tank barrel and communicated with the blow-off pipe, and the blow-off valve is arranged on the blow-off pipe and used for controlling the conduction of the blow-off pipe; the boiling ring is positioned in the sealed sewage draining groove cylinder body; and the air blowing valve is positioned on the side wall of the sealed sewage drainage tank barrel.

The top of the sealed sewage draining groove barrel is also provided with a second pipeline hole for the external sewage inflow pipe to extend into the sealed sewage draining groove barrel.

Preferably, the sealed sewage draining tank further comprises an external sewage inflow pipe, and the external sewage inflow pipe extends from the second pipeline hole to the inside of the sealed sewage draining tank barrel; and a sewage draining outlet is arranged at the bottom of the shell of the cyclone separator and communicated with the top of an external sewage inflow pipe.

Preferably, the bottom of the external filth inflow pipe is chamfered, preferably, the chamfered is directed toward the filth discharge pipe, and more particularly, the chamfered is formed at an angle of 30 to 70 degrees with respect to the horizontal plane.

Preferably, the boiling ring is provided with a hollow pipeline, and air outlets which are used for communicating the hollow pipeline with the inside of the sealed sewage draining groove cylinder body are arranged along the hollow pipeline.

In a preferred embodiment, the air outlet is located at the lower part of the hollow pipe and is opened downwards, namely towards the bottom of the sealed sewage draining tank cylinder.

In a preferred embodiment, the air outlets are evenly arranged along the hollow duct.

In a preferred embodiment, the outlet openings are preferably 6-8mm in diameter.

In a preferred embodiment, the boiling ring is disposed in the sealed sewage trough cylinder at an angle. More preferably, the upper end of the boiling ring leans against the inner wall of the sealed sewage drainage tank barrel, and the lower end of the boiling ring is positioned at the bottom of the sealed sewage drainage tank barrel.

More preferably, the bottom end of the boiling ring is positioned at the joint of the side wall and the bottom of the sealed sewage draining groove barrel.

Preferably, the boiling ring is connected with the inner wall of the sealed sewage draining groove cylinder into a whole, and the included angle between the boiling ring and the horizontal plane is 5-30 degrees.

Preferably, the blowing valve is connected with a gas conveying pipe, and the gas conveying pipe extends into the sealed sewage draining groove cylinder and is communicated to a hollow pipeline of the boiling ring.

In a preferred embodiment, the air blowing valve is connected with an external high-pressure air source. Preferably, the high-pressure gas source refers to a high-pressure gas source with pressure greater than atmospheric pressure, such as a gas tank, a gas pump and the like, and the high-pressure gas source is preferably 3-6 bar.

Preferably, the sealed sewage draining tank further comprises an overflow pipe, and the overflow pipe is located on the outer wall of the top of the sealed sewage draining tank barrel.

Preferably, the sealed sewage draining tank further comprises a liquid level meter for measuring and/or displaying the liquid level height in the cylinder of the sealed sewage draining tank. Preferably, the liquid level meter is a round tubular rod body with a closed junction box.

Preferably, the gauge is provided with at least two sensors for measuring the level: a first sensor and a second sensor; preferably, the first sensor and the second sensor are different in height. More preferably, the first sensor is located at a position close to the bottom of the circular tube-shaped rod body relative to the second sensor; the second sensor is located at a position close to the top of the round tubular rod body relative to the first sensor.

Preferably, the top of the sealed sewage draining groove barrel is also provided with an insertion hole of the liquid level meter, the liquid level meter is inserted into the barrel of the sealed sewage draining groove through the insertion hole, and preferably, at least part of the liquid level meter is positioned outside the sealed sewage draining groove barrel, for example, the part with the sealed junction box is positioned outside the sealed sewage draining groove barrel; the first sensor and the second sensor are positioned in the sealed sewage draining groove cylinder.

The invention has the technical effects and advantages that: the vacuum sewage discharging device can rotate the separator along the input port at the lowest point of the separator no matter which input or which inputs the vacuum is generated by a vacuum fan or other vacuum sources, the cyclone separator is rotated and separated, liquid and pollutant stickies in the liquid flow into the sealed water tank at the highest speed, the quick gas-liquid separation is completed without solidifying and condensing the stickies, meanwhile, the cyclone separator is opened from a cleaning valve to wash the inner wall of the cyclone separator, then the vacuum fan sucks out gas in the vacuum fan, vacuum is generated in the separator, the liquid and the pollutant in the inlet of the separator flow into the lower sealed sewage discharging tank along the conical surface at the bottom of the separator at a certain flow rate, after a certain amount of pollutant is collected by the sealed water tank, the flowing stickies in the sealed sewage discharging tank are boiled through the combination of a blowing valve and a boiling ring of the sealed sewage discharging tank, then flows out along with the sewage discharge pipe at the bottom of the sealed sewage discharge tank, so that the problem that the sewage discharge pipeline is blocked because the adhesive sewage is not thoroughly removed and is not condensed in time in the sewage discharge pipeline in life is effectively solved.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the application and, together with the description, serve to explain the application and are not intended to limit the application. In the drawings:

FIG. 1 is a schematic front view of a vacuum waste that automatically separates gases and liquids and contaminants therein in accordance with the present invention;

FIG. 2 is a schematic left side view of the vacuum waste of the present invention automatically separating gases and liquids and contaminants therein;

fig. 3 is a perspective view of the vacuum sewage apparatus for automatically separating gas and liquid and contaminants therein according to the present invention.

FIG. 4 is a schematic view of a sealed sewage drainage tank of a vacuum sewage drainage apparatus for automatically separating gas and liquid and pollutants therein according to the present invention

Illustration of the drawings:

1 flashboard control box, 2 cyclone separators, 3 sealed sewage draining grooves, 4 vacuum fans, 5 sewage suction pipes, 6 flashboard valves, 7 boiling rings, 8 blow-off valves, 9 blow-off pipes, 10 air blowing valves, 11 vacuum fan air inlet pipes, 12 transparent windows, 13 self-cleaning valves, 14 liquidometers, 15 overflow pipes, 16 vacuum fan air outlet pipelines, 17 bearing plates and 18 sewage inflow pipes.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

Referring to fig. 1-3, a vacuum sewage device for automatically separating gas and liquid and pollutants therein is used for separating gas-liquid mixture containing pollutants such as stickies.

The vacuum sewage apparatus for automatically separating gas and liquid and pollutants therein includes: an upper and a lower part, which are delimited by a carrier plate 17. The bearing plate 17 is not limited to the form, and may be a floor surface, or a bearing plate separately provided. In the upper part of the carrying plate 17, a shutter control box 1, a cyclone 2, and a vacuum fan 4 are provided. The part below the bearing plate 17 is provided with a sealed sewage draining groove 3.

The gate plate control box 1 comprises a sewage suction pipe 5 and gate valves 6 for controlling the communication state of the sewage suction pipe, specifically, the sewage suction pipe 5 is provided with three groups, and one or more of the gate valves 6 are controlled to be switched on and off. And an air cylinder and an electromagnetic valve are further arranged in the gate plate control box 1 and are used for controlling the communication state of the gate plate valve. The communication and closing of the desired contaminant suction pipe 5 therein are controlled by the operation of the cylinder and the solenoid valve.

The cyclone separator 2 comprises a shell, the shell is provided with a sewage draining outlet, the sewage draining outlet is communicated with the sealed sewage draining groove 3 downwards, and specifically, the top of the sealed sewage draining groove 3 is provided with an opening communicated with the sewage draining outlet of the cyclone separator 2 through a section of hollow pipe (a sewage inflow pipe 18).

The shell is provided with an air suction opening which is communicated with an air suction opening of the vacuum fan 4 through a vacuum fan air inlet pipe 11, and the vacuum fan 4 discharges sucked air through a vacuum fan air outlet pipeline 16; the sewage suction pipe 5 is communicated with the inlet of the cyclone separator 2 through a sewage inlet pipeline, and the inlet of the sewage inlet pipeline is lower than the air suction port and higher than the sewage discharge port. A transparent window 12 is further arranged in the middle of the dirt inlet pipeline communicated with the dirt suction pipe 5 of the cyclone separator 2, and more preferably, the transparent window is communicated with the inlet of the cyclone separator and the dirt inlet pipeline through a connecting flange.

The sealed sewage drainage tank 3 comprises a boiling ring 7, a blow-off valve 8, a blow-off pipe 9 and a blowing valve 10, the bottom of the side wall of the cylinder body of the sealed sewage drainage tank 3 is provided with an opening communicated with the blow-off pipe 9, the blow-off valve 8 is connected to the blow-off pipe 9, and the boiling ring 7 is positioned in the cylinder body of the sealed sewage drainage tank 3. Specifically, the boiling ring 7 is obliquely arranged in the cylinder of the sealed sewage drainage tank 3. More preferably, the boiling ring 7 is inclined against the inner wall of the sealed sewage drainage tank 3 at the upper end and at the bottom of the sealed sewage drainage tank 3 at the lower end. More preferably, the bottom end of the boiling ring 7 is located at the joint of the inner wall and the bottom of the cylinder of the sealed sewage drainage tank 3.

The air blowing valve 10 is positioned on the side wall of the cylinder body of the sealed sewage drainage tank 3 and feeds air into the boiling ring 7. In the sealed sewage drainage tank 3, the boiling ring 7 is provided with a hollow pipeline and an air outlet which communicates the hollow pipeline with the cylinder of the sealed sewage drainage tank 3. Specifically, the air blowing valve 10 is connected with an air delivery pipe, and the air delivery pipe extends into the cylinder of the sealed sewage drainage tank 3 and is communicated to a hollow pipeline of the boiling ring 7. Specifically, the boiling ring 7 is disposed at an angle to the bottom of the sealed sewage drain tank cylinder 3. More specifically, the boiling ring 7 has an upper end leaning against the inner wall of the sealed sewage drainage tank cylinder 3 and a lower end at the bottom of the sealed sewage drainage tank cylinder 3. More specifically, the bottom end of the boiling ring 7 is positioned at the joint of the inner wall and the bottom of the sealed sewage drainage tank 3 barrel. The boiling ring 7 is annularly arranged with the bottom of the cylinder body as a whole, and the horizontal included angle is 5-30 degrees. The boiling ring 7 is provided with a hollow pipeline, a plurality of downward small holes are arranged at the lower part of the hollow pipeline, and the small holes are communicated with the inner cavity of the sealed water tank. More specifically, a plurality of small holes with the diameter of 6-8mm are uniformly distributed at the lower part of the hollow pipeline.

The external air source of the air blowing valve 10 can be a high-pressure air source (for example, air with a pressure of 3-6 bar), such as an air storage tank, a blower, etc. In some cases, the vacuum blower outlet duct 16 connected to the vacuum blower 4 may be used to blow air into the sealed sewage drain tank 3 while performing cyclone separation.

The sewage inflow pipe 18 is inserted from a circular hole at the top of the sealed sewage draining groove 3 and is welded and fixed, the bottom of the sewage inflow pipe 18 is provided with an oblique plane, the oblique plane faces the sewage draining pipe, and more particularly, the angle between the oblique plane and the horizontal plane is 30-70 degrees, so that pollutants can be dispersed uniformly and quickly when being drained.

When the vacuum sewage discharging device works, the flashboard valve control box 1 and the vacuum fan 4 are powered on, the switch of the flashboard valve 6 is turned on, the vacuum fan 4 is turned on, negative pressure is formed in the cyclone separator 2 through the vacuum fan air inlet pipe 11, so that a gas-liquid mixture to be treated containing sticky dirt is sucked into a cylinder of the cyclone separator 2, the separation speed can be adjusted within the range of 0-90 degrees, and the angle beta between the inlet central line of a sewage inlet pipeline of the cyclone separator 2 and the horizontal line is not less than 0 and a is less than 45 degrees. The sucked gas-liquid mixture to be treated enters from the bottom or the middle lower part of the cyclone separator 2 and rises up in a rotating manner for rotating centrifugal separation. The sticky thing filth and the liquid that separate out in the cyclone 2 send into the sealed sewage drainage tank 3 in the below, and boiling ring 7 in the sealed sewage drainage tank 3 can make the sticky thing filth boil and open blowoff valve 8 outside through blow off pipe 9 with sticky thing filth eduction gear, has effectively solved the clearance of pollutant (containing sticky thing) dirt processing in-process unclean, the problem of solidification coagulation easily.

Example 2

On the basis of the embodiment 1, the cyclone separator 2 is further provided with two groups of self-cleaning valves 13 which are respectively positioned at the left side and the right side of the top cylinder cover of the cylinder body of the cyclone separator 2 or above the top cylinder cover.

When the cyclone separator is used for self-cleaning, self-cleaning water is added from the upper part and the side surface of the cyclone separator to clean the inner wall of the cyclone separator, the downflow water carries sticky pollutants to enter a sealing sewage discharge groove 3 below, at the moment, a blow-off valve 8 and an air valve 10 are opened, 3-6bar high-pressure gas enters a boiling ring 7 through a blowing valve 10 and enters the sealing sewage discharge groove 3, the liquid mixture in the sealing sewage discharge groove 3 starts to boil and turn over, and the fully-mixed liquid mixture is slowly discharged through the blow-off valve, so that the effect of completely cleaning the inside of the sealing water groove without dead angles can be realized

The sealed sewage draining tank 3 further comprises an overflow pipe, and the overflow pipe is located on the outer wall of the right side of the top of the barrel body of the sealed sewage draining tank 3.

The sealed sewage draining tank 3 further comprises a liquid level meter 14 which is a round tubular rod body with a sealed junction box. More preferably, the gauge is further provided with two sensors for measuring the level. More preferably, the sensors are located one near the bottom of the tubular rod and one near the top of the tubular rod. The top of the cylinder of the sealed sewage draining tank 3 is also provided with a jack of the liquid level meter 14.

Specifically, when the vacuum sewage discharging device works, the flashboard valve control box 1 and the vacuum fan 4 are connected with a power supply, the self-cleaning water valve of the cyclone separator is connected with a water source, the switch of the flashboard valve 6 is opened, the sticky dirt is sucked into the cylinder of the cyclone separator through the dirt suction pipe 5 for stirring and separating, then the cyclone separator is opened to clean the self-cleaning water valve for cleaning the inner wall of the cyclone separator 2, the vacuum fan 4 conveys vacuum gas into the cyclone separator 2 through the vacuum fan gas outlet pipeline 12, the sticky dirt in the cyclone separator 2 is pressed into the sealed sewage discharging groove 3 through vacuum gas compression, the boiling ring 7 in the sealed sewage discharging groove 3 can boil the sticky dirt and open the sewage discharging valve 8 to discharge the sticky dirt out of the device through the sewage discharging pipe 9, and the problem that the dirt (including the sticky dirt) cannot be cleaned cleanly in the treatment process is effectively solved, easy solidification and coagulation.

The embodiments of the present invention have been described in detail, but the embodiments are merely examples, and the present invention is not limited to the embodiments described above. Any equivalent modifications and substitutions to those skilled in the art are also within the scope of the present invention. Accordingly, equivalent changes and modifications made without departing from the spirit and scope of the present invention should be covered by the present invention.

Claims

1. A vacuum sewage discharge device capable of automatically separating gas, liquid and pollutants therein is characterized by comprising a flashboard control box, a cyclone separator, a sealed sewage discharge groove and a vacuum fan, wherein the sealed sewage discharge groove is positioned below the cyclone separator;

2. The vacuum sewage apparatus for automatically separating gas and liquid and pollutant therein according to claim 1 wherein said pollutant suction pipe is provided with at least three sets or more, and on-off operation of one or more of them is controlled by said gate valve.

3. The vacuum sewage apparatus for automatically separating gas and liquid and contaminants therein according to claim 1, wherein a cylinder and a solenoid valve are further provided in the gate control box for controlling the communication state of the gate valve.

4. The vacuum sewer apparatus for automatically separating gas and liquid and pollutant therein according to claim 1, wherein said cyclone separator is further provided with two sets of self-cleaning valves respectively located at left and right sides of a top cover of a cylinder of said cyclone separator.

5. The vacuum sewage apparatus for automatically separating gas and liquid and pollutant therein according to claim 1, wherein the included angle α between the inlet centerline of the sewage inlet pipe of the cyclone separator and the vertical inner wall of the cyclone separator is not more than 90 °, and the angle β with the horizontal line is 0- β <45 °.

6. The vacuum sewage apparatus for automatically separating gas and liquid and pollutant therein according to claim 1, wherein a transparent window is further provided in the middle of the sewage inlet pipe communicating the cyclone separator and the gas-liquid mixture pollutant-containing suction pipe, and the transparent window is communicated with the cyclone separator inlet and the sewage inlet pipe through a connecting flange.

7. The vacuum sewage apparatus for automatically separating gas and liquid and pollutant therein according to claim 1 wherein the top of said sealed sewage draining tank is provided with an opening communicated with the sewage outlet of said cyclone separator through a section of vacuum pipe.

8. The vacuum sewage apparatus for automatically separating gas and liquid and pollutants therein according to claim 1, wherein the sealed sewage draining tank comprises a sealed sewage draining tank cylinder, a boiling ring, an air blowing valve, a sewage draining valve and a sewage draining pipe; the device comprises a sealed sewage draining tank barrel, a blow-off valve, a blow-off pipe, a blow-off valve and a control valve, wherein the blow-off pipe and the blow-off valve are positioned outside the sealed sewage draining tank barrel, a first pipeline hole is formed in the side wall of the sealed sewage draining tank barrel and communicated with the blow-off pipe, and the blow-off valve is arranged on the blow-off pipe and used for controlling the conduction of the blow-off pipe; the boiling ring is positioned in the sealed sewage draining groove cylinder body; and the air blowing valve is positioned on the side wall of the sealed sewage drainage tank barrel.

9. The vacuum sewer apparatus for automatically separating gas and liquid and pollutant therein according to claim 8, wherein said boiling ring is obliquely disposed in the cylinder of said sealed sewage drainage tank; the upper end of the boiling ring is obliquely leaned against the inner wall of the sealed sewage drainage tank cylinder, and the lower end of the boiling ring is positioned at the bottom of the sealed sewage drainage tank cylinder; the bottom end of the boiling ring is positioned at the joint of the inner wall and the bottom of the cylinder of the sealed sewage drainage tank.

10. The vacuum sewage apparatus for automatically separating gas and liquid and pollutant therein according to claim 8, wherein the top of said sealed sewage drainage tank cylinder is further provided with a second pipe hole; the sealed sewage draining groove also comprises an external sewage inflow pipe, and the external sewage inflow pipe extends into the cylinder of the sealed sewage draining groove from the second pipeline hole; a sewage draining outlet is formed in the bottom of the shell at the bottom of the shell of the cyclone separator and communicated with the top of an external sewage inflow pipe; the bottom of the external sewage inflow pipe is an oblique cut surface, the oblique cut surface faces the direction of the sewage discharge pipe, and the included angle between the oblique cut surface and the horizontal plane is 30-70 degrees.