CN221191776U - Novel inclined tube sedimentation integrated water treatment device - Google Patents

Abstract

The utility model discloses a novel inclined tube sedimentation integrated water treatment device, which comprises a shell, flocculation balls, turbulators, inclined tube fillers and a filter screen, wherein the flocculation balls are arranged on the shell; a sludge hopper matched with the turbulator is sleeved on the coaxial center of the middle lower position in the shell, the turbulator is arranged right above the corresponding sludge hopper in the shell at intervals, a first cylinder is sleeved in the inner ring of the turbulator, a second cylinder with a trapezoid cross section is arranged on the upper surface of the turbulator, the second cylinder is respectively communicated with the first cylinder and the turbulator, and flocculation balls are filled in the first cylinder and the second cylinder; a filter screen is vertically arranged on the upper end surface of the second cylinder, and a plurality of inclined tube fillers are uniformly distributed and obliquely arranged on the outer circumferential surface of the filter screen; one end of the water inlet pipe penetrates through the sludge hopper and then is communicated with the lower end of the first cylinder, and one end of the water outlet pipe penetrates through the second cylinder and then is vertically upwards communicated with the lower end of the filter screen in a sealing manner, so that a circulating loop for sewage mixing, sedimentation and filtration is formed. The utility model saves the cost and improves the quality of the effluent.

Description

Novel inclined tube sedimentation integrated water treatment device

Technical Field

The utility model relates to the technical field of sewage treatment, in particular to a novel inclined tube sedimentation integrated water treatment device.

Background

The existing inclined tube precipitator is characterized in that oil, suspended matters and the like in water are settled and separated through condensation and flocculation after chemical agents are added, so that the aim of purifying water quality is fulfilled; but the problems of insufficient mixing degree of the medicaments, insufficient hydraulic retention time, incapability of timely discharging sludge accumulation, excessive suspended matters in the effluent, great consumption of manpower flushing and the like generally exist. Therefore, the above problems need to be solved.

Disclosure of Invention

The utility model aims to solve the technical problem of providing a novel inclined tube sedimentation integrated water treatment device, which is characterized in that a flocculating ball and a turbulator are matched for use to fully mix a medicament with sewage, so that a stirring impeller is replaced, the cost is saved, and the hydraulic retention time is improved.

In order to solve the technical problems, the utility model adopts the following technical scheme: the utility model relates to a novel inclined tube sedimentation integrated water treatment device, which has the innovation points that: comprises a shell, flocculation balls, turbulators, inclined tube fillers, a filter screen, a water inlet pipe and a water outlet pipe; the shell is of a hollow cylinder structure which is vertically arranged, a sludge hopper matched with the shell is horizontally and concentrically arranged at the middle lower position in the shell, the turbulator is coaxially arranged right above the sludge hopper at intervals in the shell, a first cylinder body which is open up and down is also coaxially sleeved in the inner ring of the shell, a second cylinder body with a trapezoid cross section is also coaxially arranged on the upper surface of the shell, the lower end of the second cylinder body is open and is respectively communicated with the first cylinder body and the turbulator, and flocculation balls are also filled in the first cylinder body and the second cylinder body; a hollow cylindrical filter screen is further vertically and coaxially arranged on the upper end face of the second cylinder body relative to the inside of the shell, and a plurality of inclined tube fillers are further uniformly distributed and obliquely arranged on the outer circumferential surface of the filter screen along the circumferential direction of the filter screen; one end of the water inlet pipe horizontally extends into the shell, passes through the sludge hopper and is vertically upwards communicated with the lower end of the first barrel in a sealing manner; one end of the water outlet pipe horizontally extends to the inside of the shell, vertically upwards communicates with the lower end of the filter screen after penetrating through the second cylinder body in a sealing way, and then a circulating loop for sewage mixing, sedimentation and filtration is formed.

Preferably, the sludge hopper is of a funnel-shaped structure which is horizontally arranged, and the upper end of the sludge hopper is a large-diameter end and is fixedly connected with the inner circumferential wall of the shell in a sealing way; vibration motors are also symmetrically arranged on the outer circumferential wall of the sludge hopper.

Preferably, the upper and lower ends of the first cylinder vertically extend out of the upper and lower surfaces of the turbulator respectively, and the upper end thereof vertically extends up to an inner lower position of the second cylinder.

Preferably, the lower end of the second cylinder body is a large-diameter end, is matched with the outer diameter of the turbulator, and is fixedly arranged on the upper surface of the turbulator; the upper end of the second cylinder body is a small-diameter end and is matched with the outer diameter of the filter screen, and the filter screen arranged vertically is supported.

Preferably, each inclined tube filler adopts hexagonal honeycomb inclined tube filler, and the set inclined angle is consistent with the trapezoid angle of the second cylinder; the lower end of each inclined tube filler is arranged in the same vertical plane with the outer circumferential surface of the second cylinder body, and the upper end of each inclined tube filler is arranged towards the outer circumferential surface direction of the filter screen and is not contacted with the filter screen.

Preferably, the water inlet pipe is arranged at the middle position of one side of the outer part of the shell relative to the sludge hopper, one end of the water inlet pipe horizontally seals and extends to the interior of the sludge hopper, and is vertically upwards communicated with the lower end of the first cylinder in a coaxial and sealed manner; two water inlet valves are sequentially arranged on the water inlet pipe at intervals relative to the outside of the shell; the water outlet pipe is arranged at the middle position of one side of the outer part of the shell relative to the second cylinder body and is arranged at the same side with the water inlet pipe, one end of the water outlet pipe horizontally seals and extends to the inner part of the second cylinder body, and then vertically upwards extends out of the upper end surface of the second cylinder body and is communicated with the lower end of the filter screen in a coaxial and sealed manner; two water outlet valves are sequentially arranged on the water outlet pipe at intervals relative to the outside of the shell.

Preferably, the device also comprises a drain pipe and a drain valve; the sewage draining pipe is arranged at the lower part of the sludge hopper relative to one side of the outer part of the shell and is arranged at the same side with the water inlet pipe, one end of the sewage draining pipe horizontally and hermetically extends to the inner part of the shell, and is hermetically communicated with the lower end of the sludge hopper in a coaxial center in an upward inclined way; two drain valves are sequentially arranged on the drain valve at intervals relative to the outside of the shell.

Preferably, the device also comprises an overrun pipe and a blowdown communication valve; overrun pipes are respectively arranged between the water inlet pipe and the water outlet pipe and between the water inlet pipe and the sewage drain pipe, and each overrun pipe is also respectively provided with a sewage drain communicating valve; one end of the overrunning pipe between the water inlet pipe and the water outlet pipe is communicated with the water outlet pipe in a sealing way relative to the middle position of the two water outlet valves, and the other end of the overrunning pipe is communicated with the water inlet pipe in a sealing way relative to the middle position of the two water inlet valves; one end of the overrun pipe between the water inlet pipe and the drain pipe is communicated with the middle position of the water inlet pipe relative to the two water inlet valves in a sealing way, and the other end of the overrun pipe is communicated with the drain pipe in a sealing way relative to the middle position of the two drain valves.

Preferably, the motor further comprises a first motor, a coupler, a rotating shaft and a steel brush; the middle position of the upper surface of the shell is also vertically provided with a first motor, and the output end of the first motor vertically extends downwards to the inside of the shell and is connected with the upper end of the rotating shaft in a coaxial linkage manner through a coupler; the rotating shafts are coaxially arranged right above the filter screen at intervals, and the steel brush is of an inverted U-shaped structure matched with the filter screen and is sleeved on the filter screen coaxially; the open end of the steel brush is downward, and the upper surface of the steel brush is fixedly connected with the lower end coaxial center of the rotating shaft.

Preferably, a manhole is further vertically embedded in an outer wall of the shell relative to the inclined tube filler and the turbulator, and each manhole is arranged on the other side relative to the water inlet pipe.

The utility model has the beneficial effects that:

(1) According to the utility model, through the matched use of the flocculation ball and the turbulator, the medicament and the sewage are fully mixed, so that a stirring impeller is replaced, the cost is saved, and the hydraulic retention time is improved;

(2) The inclined tube filler is arranged, so that the suspended matter removal efficiency can be improved;

(3) According to the utility model, the filter screen is arranged, so that the content of suspended matters in the effluent is greatly reduced, and the quality of the effluent is effectively improved;

(4) The utility model can regularly carry out sewage discharge and backwashing, and the sludge hopper is assisted to discharge sludge by the vibrating motor, thereby solving the problem of sludge accumulation, reducing manpower, saving occupied space, reducing investment cost and improving the quality of discharged water.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a novel inclined tube sedimentation integrated water treatment device.

Fig. 2 is a schematic view of the water flow direction of the normal automatic water purification process of the present utility model.

Wherein, 1-a first motor; 2-a filter screen; 3-steel brush; 4-inclined tube filling; 5-flocculating balls; 6-turbulators; 7-overrunning tube; 8-a vibration motor; 9-a water inlet pipe; 10-a water outlet pipe; 11-a blow-down pipe; 12-a sewage discharge communicating valve; 13-a housing; 14-a first cylinder; 15-a second cylinder; 16-a sludge bucket; 17-manhole; 18-a water inlet valve; 19-a water outlet valve; 20-a blow-down valve.

Detailed Description

The technical scheme of the present utility model will be clearly and completely described in the following detailed description.

The utility model relates to a novel inclined tube sedimentation integrated water treatment device which comprises a shell 13, a flocculation ball 5, a turbulator 6, an inclined tube filler 4, a filter screen 2, a water inlet pipe 9 and a water outlet pipe 10; as shown in fig. 1 and 2, the shell 13 is a hollow cylinder structure which is vertically arranged, a sludge bucket 16 which is matched with the shell is also horizontally and concentrically arranged at the middle lower position in the shell, the sludge bucket 16 is a funnel-shaped structure which is horizontally arranged, the upper end of the sludge bucket is a large-diameter end, and the sludge bucket is fixedly connected with the inner circumferential wall of the shell 13 in a sealing way; the vibration motor 8 is also symmetrically arranged on the outer circumferential wall of the sludge hopper 16, and the vibration motor 8 is used for assisting the sludge in the sludge hopper 16 to fall off.

The turbulator 6 is arranged in the shell 13 at intervals right above the sludge hopper 16, a first cylinder 14 with an open upper part and a lower part is also sleeved in the inner ring of the turbulator, a second cylinder 15 with a trapezoid cross section is also coaxially arranged on the upper surface of the turbulator, the lower end of the second cylinder 15 is open and is respectively communicated with the first cylinder 14 and the turbulator 6, and flocculation balls 5 are also filled in the first cylinder 14 and the second cylinder 15; as shown in fig. 1, the upper and lower ends of the first cylinder 14 extend vertically out of the upper and lower surfaces of the turbulator 6, respectively, and the upper ends thereof extend vertically upward to the inner lower position of the second cylinder 15, and ensure that the flocculation ball 5 fills the inner parts of the first cylinder 14 and the second cylinder 15 irregularly, and further, sewage and the medicament are fully mixed through the cooperation of the flocculation ball 5 and the turbulator 6.

As shown in fig. 1, the lower end of the second cylinder 15 is a large-diameter end, is matched with the outer diameter of the turbulator 6, and is fixedly arranged on the upper surface of the turbulator 6, so that the mixed sewage is ensured to flow out from the lower surface of the turbulator 6, and then flows upwards into the inclined tube filler 4 for precipitation; the upper end of the second cylinder 15 is a small diameter end, is matched with the outer diameter of the filter screen 2, and supports the filter screen 2 which is vertically arranged.

The utility model is provided with a hollow cylindrical filter screen 2 vertically and coaxially relative to the inside of a shell 13 on the upper end surface of a second cylinder 15, and a plurality of inclined tube fillers 4 are uniformly distributed and obliquely arranged on the outer circumferential surface of the filter screen 2 along the circumferential direction; as shown in fig. 1 and 2, each inclined tube filler 4 adopts a hexagonal honeycomb inclined tube filler 4, and the set inclined angle is consistent with the tread angle of the second cylinder 15; the lower end of each inclined tube filler 4 is arranged in the same vertical plane with the outer circumferential surface of the second cylinder 15, and the upper end of each inclined tube filler is arranged towards the outer circumferential surface direction of the filter screen 2 and is not contacted with the filter screen 2, so that mixed sewage is introduced into the filter screen 2 for filtration, and the sedimentation of flocculate is accelerated through the inclined tube filler 4 in the process.

As shown in fig. 1 and 2, the water inlet pipe 9 is arranged at the middle position of one side of the outer part of the shell 13 relative to the sludge hopper 16, one end of the water inlet pipe is horizontally sealed and extends to the interior of the sludge hopper 16, and is vertically upwards communicated with the lower end of the first cylinder 14 in a coaxial and coaxial way, and is ensured to be arranged in a non-interfering way with the first motor 1, so that sewage is led into the first cylinder 14 through the water inlet pipe 9 and is fully mixed with the medicament through the cooperation of the flocculation ball 5 and the turbulator 6; two water inlet valves 18 are sequentially arranged on the water inlet pipe 9 at intervals relative to the outside of the shell 13, and the on-off of the water inlet pipe 9 is controlled through the water inlet valves 18;

As shown in fig. 1 and 2, the water outlet pipe 10 is arranged at the middle position of one side of the outer part of the shell 13 relative to the second cylinder 15 and is arranged at the same side as the water inlet pipe 9, one end of the water outlet pipe 10 horizontally seals and extends to the inner part of the second cylinder 15, then vertically upwards extends out of the upper end surface of the second cylinder 15 and is coaxially and hermetically communicated with the lower end of the filter screen 2, and then the mixed, precipitated and filtered sewage is discharged; two water outlet valves 19 are sequentially arranged on the water outlet pipe 10 at intervals relative to the outside of the shell 13, and then the on-off of the water outlet pipe 10 is controlled through the water outlet valves 19.

As shown in fig. 1 and 2, the drain pipe 11 is arranged at a position below the sludge hopper 16 on one side of the outer part of the shell 13 and is arranged on the same side as the water inlet pipe 9, one end of the drain pipe 11 horizontally and hermetically extends to the inner part of the shell 13, and is hermetically communicated with the lower end of the sludge hopper 16 in a coaxial center in an upward inclined way; two drain valves 20 are sequentially arranged on the drain valve 20 at intervals relative to the outside of the shell 13, and then the on-off of the drain pipe 11 is controlled through the drain valves 20.

The utility model is also provided with the overrun pipes 7 between the water inlet pipe 9 and the water outlet pipe 10 and between the water inlet pipe 9 and the blow-down pipe 11, and each overrun pipe 7 is also provided with a blow-down communicating valve 12, so that the on-off of the corresponding overrun pipe 7 is controlled through the blow-down communicating valve 12; one end of the overrunning pipe 7 positioned between the water inlet pipe 9 and the water outlet pipe 10 is communicated with the water outlet pipe 10 in a sealing way relative to the middle position of the two water outlet valves 19, and the other end of the overrunning pipe is communicated with the water inlet pipe 9 in a sealing way relative to the middle position of the two water inlet valves 18; one end of the overrun pipe 7 between the inlet pipe 9 and the drain pipe 11 is in sealed communication with the inlet pipe 9 in a position intermediate the two inlet valves 18 and the other end thereof is in sealed communication with the drain pipe 11 in a position intermediate the two drain valves 20.

As shown in fig. 1 and 2, a first motor 1 is further vertically arranged in the middle of the upper surface of the shell 13, and the output end of the first motor 1 vertically extends downwards to the inside of the shell 13 and is connected with the upper end of a vertically arranged rotating shaft in a coaxial linkage manner through a coupler; the rotating shafts are coaxially arranged right above the filter screen 2 at intervals, and the steel brush 3 is of an inverted U-shaped structure matched with the filter screen 2 and is coaxially sleeved on the filter screen 2; the open end of the steel brush 3 is arranged downwards, the upper surface of the steel brush is fixedly connected with the lower end of the rotating shaft in a coaxial mode, and then the steel brush 3 rotates around the filter screen 2 under the driving of the first motor 1 to clean the filter screen 2, and the steel brush 3 is ensured to not influence the filtering action of the precipitated sewage entering the filter screen 2.

As shown in fig. 1, a manhole 17 is also vertically embedded in an outer wall of the housing 13 at a position corresponding to the inclined tube filler 4 and the turbulator 6, and each manhole 17 is arranged at the other side corresponding to the water inlet pipe 9, so that the water enters the housing 13 through the manhole 17 for maintenance.

The working principle of the utility model is as follows:

In the normal automatic water purification process, as shown in fig. 2, the water inlet valve 18 and the water outlet valve 19 are first opened, and the drain valve 20 and the drain communication valve 12 are closed; then sewage enters the first cylinder 14, the second cylinder 15 and the turbulator 6 in sequence through the water inlet pipe 9, and is fully mixed with the medicament through the cooperation of the flocculation ball 5 and the turbulator 6; then the mixed sewage flows out from the lower surface of the turbulator 6, then enters the inclined tube filler 4 upwards from the outside of the turbulator 6, the inclined tube filler 4 is utilized to divide the water flow into a series of shallow precipitation layers, suspended matters and oils flocculate and deposit on the inclined tube filler 4, a large amount of sludge also settles in the inclined tube filler 4 and automatically slides into the sludge hopper 16, the settled water flow carries the residual fine suspended matters into the filter screen 2, and the water is discharged through the water outlet pipe 10 after being filtered and adsorbed by the filter screen 2;

When reaching the set period, the back washing and pollution discharge are needed, and the specific operation is as follows: firstly, the water inlet valve 18 and the sewage communication valve 12 are closed, and the sewage valve 20 and the water outlet valve 19 are opened; then, under the drive of the first motor 1, the steel brush 3 rotates to clean the filter screen 2, at the moment, as the blow-off valve 20 is opened, the water inlet valve 18 is closed, the water level in the shell 13 is lowered, and the water discharged by other devices enters the water outlet pipe 10, so that the filter screen 2 and the inclined tube filler 4 are backwashed, backwashed sewage is discharged through the sludge hopper 16 through the blow-off pipe 11, and the process is assisted by the vibrating motor 8 to fall off sludge;

When the maintenance is needed, the corresponding water inlet valve 18, the water outlet valve 19 and the sewage discharging valve 20 close to the side of the shell 13 are closed, the sewage discharging communication valve 12 is opened, a loop can be formed through the overrunning pipe 7, the device is bypassed at the moment, and accordingly the sewage can enter the shell 13 through the manhole 17 for maintenance.

The utility model has the beneficial effects that:

(1) According to the utility model, through the matched use of the flocculation ball 5 and the turbulator 6, the medicament and the sewage are fully mixed, so that a stirring impeller is replaced, the cost is saved, and the hydraulic retention time is improved;

(2) The inclined tube filler 4 is arranged, so that the suspended matter removal efficiency can be improved;

(3) According to the utility model, the filter screen 2 is arranged, so that the content of suspended matters in the effluent is greatly reduced, and the quality of the effluent is effectively improved;

(4) The utility model can regularly carry out sewage discharge and backwashing, and the sludge hopper 16 is assisted to discharge sludge by the vibrating motor 8, thereby solving the problem of sludge accumulation, reducing manpower, saving occupied space, reducing investment cost and improving the quality of discharged water.

The above embodiments are merely illustrative of the preferred embodiments of the present utility model, and the present utility model is not limited to the above embodiments, and various modifications and improvements made by those skilled in the art to the technical solutions of the present utility model without departing from the design concept of the present utility model should fall within the protection scope of the present utility model, and the claimed technical content of the present utility model is fully described in the claims.

Claims (10)

1. Novel inclined tube sedimentation integrated water treatment device is characterized in that: comprises a shell, flocculation balls, turbulators, inclined tube fillers, a filter screen, a water inlet pipe and a water outlet pipe; the shell is of a hollow cylinder structure which is vertically arranged, a sludge hopper matched with the shell is horizontally and concentrically arranged at the middle lower position in the shell, the turbulator is coaxially arranged right above the sludge hopper at intervals in the shell, a first cylinder body which is open up and down is also coaxially sleeved in the inner ring of the shell, a second cylinder body with a trapezoid cross section is also coaxially arranged on the upper surface of the shell, the lower end of the second cylinder body is open and is respectively communicated with the first cylinder body and the turbulator, and flocculation balls are also filled in the first cylinder body and the second cylinder body; a hollow cylindrical filter screen is further vertically and coaxially arranged on the upper end face of the second cylinder body relative to the inside of the shell, and a plurality of inclined tube fillers are further uniformly distributed and obliquely arranged on the outer circumferential surface of the filter screen along the circumferential direction of the filter screen; one end of the water inlet pipe horizontally extends into the shell, passes through the sludge hopper and is vertically upwards communicated with the lower end of the first barrel in a sealing manner; one end of the water outlet pipe horizontally extends to the inside of the shell, vertically upwards communicates with the lower end of the filter screen after penetrating through the second cylinder body in a sealing way, and then a circulating loop for sewage mixing, sedimentation and filtration is formed.

2. The novel inclined tube sedimentation integrated water treatment device according to claim 1, wherein: the sludge hopper is of a funnel-shaped structure which is horizontally arranged, and the upper end of the sludge hopper is a large-diameter end and is fixedly connected with the inner circumferential wall of the shell in a sealing way; vibration motors are also symmetrically arranged on the outer circumferential wall of the sludge hopper.

3. The novel inclined tube sedimentation integrated water treatment device according to claim 1, wherein: the upper end and the lower end of the first cylinder vertically extend out of the upper surface and the lower surface of the turbulator respectively, and the upper end of the first cylinder vertically extends upwards to the position of the second cylinder, which is lower than the inner part of the second cylinder.

4. A novel inclined tube sedimentation integrated water treatment device according to claim 3, characterized in that: the lower end of the second cylinder body is a large-diameter end, is matched with the outer diameter of the turbulator, and is fixedly arranged on the upper surface of the turbulator; the upper end of the second cylinder body is a small-diameter end and is matched with the outer diameter of the filter screen, and the filter screen arranged vertically is supported.

5. The novel inclined tube sedimentation integrated water treatment device according to claim 1, wherein: each inclined tube filler adopts hexagonal honeycomb inclined tube filler, and the set inclined angle of each inclined tube filler is consistent with the trapezoid angle of the second cylinder; the lower end of each inclined tube filler is arranged in the same vertical plane with the outer circumferential surface of the second cylinder body, and the upper end of each inclined tube filler is arranged towards the outer circumferential surface direction of the filter screen and is not contacted with the filter screen.

6. The novel inclined tube sedimentation integrated water treatment device according to claim 2, wherein: the water inlet pipe is arranged at the middle position of one side of the outer part of the shell relative to the sludge hopper, one end of the water inlet pipe horizontally seals and extends to the inner part of the sludge hopper, and is vertically upwards communicated with the lower end of the first cylinder in a coaxial sealing manner; two water inlet valves are sequentially arranged on the water inlet pipe at intervals relative to the outside of the shell; the water outlet pipe is arranged at the middle position of one side of the outer part of the shell relative to the second cylinder body and is arranged at the same side with the water inlet pipe, one end of the water outlet pipe horizontally seals and extends to the inner part of the second cylinder body, and then vertically upwards extends out of the upper end surface of the second cylinder body and is communicated with the lower end of the filter screen in a coaxial and sealed manner; two water outlet valves are sequentially arranged on the water outlet pipe at intervals relative to the outside of the shell.

7. The novel inclined tube sedimentation integrated water treatment device according to claim 6, wherein: the sewage treatment device also comprises a sewage discharge pipe and a sewage discharge valve; the sewage draining pipe is arranged at the lower part of the sludge hopper relative to one side of the outer part of the shell and is arranged at the same side with the water inlet pipe, one end of the sewage draining pipe horizontally and hermetically extends to the inner part of the shell, and is hermetically communicated with the lower end of the sludge hopper in a coaxial center in an upward inclined way; two drain valves are sequentially arranged on the drain valve at intervals relative to the outside of the shell.

8. The novel inclined tube sedimentation integrated water treatment device according to claim 7, wherein: the device also comprises an overrun pipe and a blowdown communication valve; overrun pipes are respectively arranged between the water inlet pipe and the water outlet pipe and between the water inlet pipe and the sewage drain pipe, and each overrun pipe is also respectively provided with a sewage drain communicating valve; one end of the overrunning pipe between the water inlet pipe and the water outlet pipe is communicated with the water outlet pipe in a sealing way relative to the middle position of the two water outlet valves, and the other end of the overrunning pipe is communicated with the water inlet pipe in a sealing way relative to the middle position of the two water inlet valves; one end of the overrun pipe between the water inlet pipe and the drain pipe is communicated with the middle position of the water inlet pipe relative to the two water inlet valves in a sealing way, and the other end of the overrun pipe is communicated with the drain pipe in a sealing way relative to the middle position of the two drain valves.

9. The novel inclined tube sedimentation integrated water treatment device according to claim 5, wherein: the motor also comprises a first motor, a coupler, a rotating shaft and a steel brush; the middle position of the upper surface of the shell is also vertically provided with a first motor, and the output end of the first motor vertically extends downwards to the inside of the shell and is connected with the upper end of the rotating shaft in a coaxial linkage manner through a coupler; the rotating shafts are coaxially arranged right above the filter screen at intervals, and the steel brush is of an inverted U-shaped structure matched with the filter screen and is sleeved on the filter screen coaxially; the open end of the steel brush is downward, and the upper surface of the steel brush is fixedly connected with the lower end coaxial center of the rotating shaft.

10. The novel inclined tube sedimentation integrated water treatment device according to claim 6, wherein: manholes are also vertically embedded in the outer wall of the shell relative to the inclined tube filler and the turbulator, and each manhole is arranged on the other side relative to the water inlet pipe.