CN214528237U - A fluidization adsorption equipment for sewage treatment - Google Patents

Abstract

The utility model relates to a fluidized adsorption device for sewage treatment, which comprises a fluidized adsorption column and a reflux device, wherein the fluidized adsorption column is sequentially provided with a water outlet area, a fluidized adsorption area and a water inlet area from top to bottom, the top end of the water inlet area is connected with the fluidized adsorption area through a water distribution plate, and the top end of the fluidized adsorption area is connected with the water outlet area through a filter component; reflux unit includes top backward flow mouth, middle part backward flow mouth, bottom backward flow mouth and switches on the back flow of three backward flow mouth, and the top backward flow mouth is established at the play basin, and the middle part backward flow mouth is established at fluidization adsorption zone, and the bottom backward flow mouth is established at intake zone or fluidization adsorption zone, launches top backward flow mouth and bottom backward flow mouth during absorption, launches middle part backward flow mouth and bottom backward flow mouth during the change adsorbent for fluidization adsorption column continuous operation.

Description

A fluidization adsorption equipment for sewage treatment

Technical Field

The utility model belongs to the technical field of sewage treatment, concretely relates to fluidization adsorption equipment for sewage treatment.

Background

With the acceleration of the urbanization process and the improvement of the living standard of people, the yield of domestic sewage and industrial wastewater is increased, and the discharge standard of sewage is stricter and stricter for creating a green and healthy environment. Among a plurality of sewage treatment methods, the adsorption method is a relatively common and mature technical means, is mainly used for removing trace pollutants, including decolorization, deodorization, removal of heavy metals, soluble organic matters, radioactive elements and the like, has the advantages of high pollutant removal efficiency, simplicity and convenience in operation and the like, can be used as a pretreatment method of methods such as ion exchange, membrane separation and the like, and can also be used as an advanced treatment means after secondary treatment to ensure the quality of reuse water.

At present, in the sewage treatment technology, a fixed bed reactor is the most commonly used adsorption equipment in sewage treatment, the flow of fluid in a bed layer is close to plug flow, and compared with a back mixing type reactor, a smaller amount of adsorbent and a smaller reactor volume can be used for obtaining larger production capacity. However, the fixed bed reactor has a small handling capacity and a high requirement on the particle size of the adsorbent. Too small an adsorbent increases the water passing pressure of the bed layer, and short flow is easily caused. The completely static adsorbent is easy to breed a biological membrane when treating actual wastewater, so that a bed layer is blocked, and the stable and efficient operation of an adsorption process is influenced. However, increasing the particle size of the adsorbent results in a large reduction in the specific surface area and a reduction in the effective content of active material, which affects the overall adsorption performance. The forming process of the adsorbent tends to be complicated and costly.

The fluidized bed reactor has the advantages of large treatment capacity, good mixing effect, difficult short flow and blockage and the like, but the fluidized bed adsorption process is commonly used in chemical unit operations such as gas catalysis and the like, and is rarely reported in wastewater treatment. Meanwhile, the fluidized bed adsorption also needs to solve the problem of loss of the adsorbent. For example, the chinese utility model patent CN209098450U provides a special system for treating chemical sewage by liquid-solid dual-bed adsorption dephenolization, which is equipped with a solid-liquid separation system behind the fluidized bed adsorption system to solve the problem of adsorbent loss. Similarly, chinese utility model CN105948321B discloses a device for treating industrial wastewater by fluidized bed adsorption-oxidation and a method for treating wastewater, which adopts a sedimentation tank and a filter to intercept the adsorbent. The mode of externally arranging a solid-liquid separation facility inevitably prolongs the treatment flow, increases the occupied area and also increases the operation and maintenance cost of the treatment system.

In summary, in both of the conventional adsorption reactors, a small-particle-size adsorbent having high adsorption performance cannot be efficiently and stably used. Meanwhile, so far, the design and operation method of the fluidized adsorption device are rarely researched in the field of sewage treatment.

SUMMERY OF THE UTILITY MODEL

To the use of above-mentioned small-size adsorbent and the loss problem of adsorbent, the utility model provides a fluidization adsorption equipment for sewage treatment based on the hydrodynamics principle, the structure is simple and easy, can use small-size adsorption material high-efficiently steadily.

The utility model provides a fluidized adsorption device for sewage treatment, which comprises a fluidized adsorption column and a reflux device, wherein the fluidized adsorption column is sequentially provided with a water outlet area, a fluidized adsorption area and a water inlet area from top to bottom; reflux unit includes top backward flow mouth, middle part backward flow mouth, bottom backward flow mouth and switches on the back flow of three backward flow mouth, and the top backward flow mouth is established at the play basin, and the middle part backward flow mouth is established at fluidization adsorption zone, and the bottom backward flow mouth is established at intake zone or fluidization adsorption zone, launches top backward flow mouth and bottom backward flow mouth during absorption, launches middle part backward flow mouth and bottom backward flow mouth during the change adsorbent for fluidization adsorption column continuous operation.

Preferably, the bottom backflow port is arranged in the water inlet area.

The fluidization adsorption device of the utility model realizes the good fluidization adsorption application of the small particle adsorbent through the fluidization adsorption column, avoids the defects of the fixed bed using the small particle adsorbent and improves the adsorption performance; meanwhile, the filtering component and the water distribution plate are adopted to intercept the adsorbent, and the fluidized adsorption device can keep continuous operation when the adsorbent is replaced by switching the reflux mode, so that the treatment capacity is improved.

Optionally, a water inlet is arranged at the bottom of the water inlet area, a water outlet is arranged in the water outlet area, the water outlet is located above the top backflow port, sewage enters from the bottom of the water inlet area, and is discharged from the water outlet of the water outlet area after being adsorbed by the fluidized adsorption area, so that adsorption treatment is completed.

Optionally, the fluidized adsorption zone is provided with a feed inlet and a discharge outlet, the feed inlet is located above the discharge outlet, and the feed rate and the discharge rate of the adsorbent are controlled by valves respectively. Preferably, the discharge port is positioned at the bottom of the fluidized adsorption zone and above the water distribution plate, so that the adsorbent can be discharged as much as possible, and residues are reduced.

Optionally, a water distribution plate is arranged at the top of the water inlet region, through holes are uniformly formed in the surface of the water distribution plate, the aperture of each through hole is smaller than the particle size of the adsorbent, the adsorbent is prevented from falling into the water inlet region, and meanwhile, after the inlet water passes through the water distribution plate, the inlet water is uniformly distributed in the radial direction of the fluidized adsorption column and uniformly passes through the fluidized adsorption region.

Optionally, the filter component is a movable filter screen, the aperture of the mesh of the movable filter screen is smaller than the particle size of the adsorbent, and the adsorbent is intercepted below the movable filter screen during fluidization movement, namely in the fluidization adsorption area, and cannot run off from the water outlet along with the water body.

Preferably, the upper surface of the movable filter screen is provided with a driving rod, the driving rod is connected with a driving device outside the fluidization adsorption column, and the driving rod drives the movable filter screen to move up and down inside the fluidization adsorption column, so that the height of the fluidization adsorption zone is adjusted in real time. Filter assembly not only can prevent that the adsorbent from running off, mobilizable design moreover, can be according to the fluctuation of the size of sewage intake load or the condition of intaking in the operation process, adjust the volume in fluidization adsorption zone in real time, change the adsorbent and satisfy the adsorption requirement under the different work condition at the fluidization state wherein and the contact state of sewage and adsorbent, guarantee steady operation and play water quality.

Optionally, the height ratio of the water inlet area, the fluidized adsorption area and the water outlet area is 1 (3-5): 0.8-1, the height-diameter ratio of the fluidized adsorption area is 3.5-5):1, the axial cross section of the water inlet area is conical, and the internal angle of the conical is 40-60 degrees.

Optionally, a flow guide scouring assembly is arranged below the filtering assembly, the flow guide scouring assembly comprises a scouring pipe and a flow guide pipe, the bottom of the scouring pipe is communicated with the flow guide pipe, the scouring pipe is cylindrical, the flow guide pipe is in a horn-mouth shape, and an included angle between a bottom opening and a horizontal plane is 30-45 degrees. In order to solve the problem of adhesion of small-particle adsorbents on the filter assembly, the utility model provides a flow-guiding scouring assembly, on one hand, after ascending water flow and adsorbents are gathered through a flow-guiding pipe and accelerated by a scouring pipe, the flow velocity is accelerated, the filter assembly above can be scoured strongly and continuously, and the adhesion of the adsorbents on the filter assembly is avoided; on the other hand, the adsorbent passing through the diversion scouring assembly flows back to the fluidized adsorption zone again through the periphery to form a ring-core flowing mode, so that the adsorbent is promoted to circulate in the fluidized adsorption zone, and the adsorption efficiency is improved.

Optionally, the flow guide flushing assembly is fixedly connected with the filtering assembly and moves up and down along with the filtering assembly.

Optionally, the diversion scouring assembly is movably connected with the filtering assembly, the driving rod is in a sleeve mode, the outer pipe is fixedly connected with the filtering assembly, the inner pipe is fixedly connected with the diversion scouring assembly, and the distance between the diversion scouring assembly and the filtering assembly is adjusted through relative movement of the inner pipe and the outer pipe so as to meet different requirements on scouring strength at different fluidizing speeds.

Optionally, the diameter of the flushing pipe is 1/10-1/4 of the inner diameter of the fluidized adsorption zone, and the opening radius of the bottom of the draft tube is 1/2-4/5 of the radius of the fluidized adsorption zone. Preferably, the diameter of the flushing pipe is 1/10-1/5 of the inner diameter of the fluidized adsorption zone, and the opening radius of the bottom of the draft tube is 1/2-3/4 of the radius of the fluidized adsorption zone.

Optionally, the diversion scouring assembly may further adopt a second form, the scouring pipe is cylindrical, the diversion pipe is in a half-bell mouth shape, i.e., half pipe walls of the diversion pipe are parallel to the scouring pipe and are on the same straight line, the other half pipe walls are in a bell mouth shape extending outwards, an included angle between the bell mouth and the horizontal plane is 30-45 degrees, and the lower edge of the diversion pipe is on the same plane. The second form of water conservancy diversion erodees the regional washing away of filter component of subassembly is applicable to and is close to fluidization adsorption zone wall, during the application, presses close to fluidization adsorption zone wall with the vertical one side of honeycomb duct, with the inside rivers region of the loudspeaker opening one side of honeycomb duct towards fluidization adsorption zone, erodees the regional filter component of being close to fluidization adsorption zone wall.

Preferably, a plurality of the flow guide scouring assemblies with the half-bell mouth are arranged at positions close to the wall surface along the circumferential direction of the fluidized adsorption zone and are fixedly connected with the flow guide scouring assemblies in the first form through connecting rods to form a whole body, and the flow guide scouring assemblies move along with the filtering assemblies;

or the flow guide scouring assembly of the half bell mouth moves up and down relative to the filtering assembly so as to adjust the relative distance between the flow guide scouring assembly of the half bell mouth and the filtering assembly;

or the flow guide scouring assembly of the half-bell mouth rotates relative to the filtering assembly so as to adjust the position of the flow guide scouring assembly of the half-bell mouth, which correspondingly scours the edge of the filtering assembly.

The second form that the subassembly was washd in the water conservancy diversion uses with the cooperation of first form, not only can wash away the filter assembly comprehensively, can form two "rings-nuclear" mobile mode moreover between two kinds of water conservancy diversion wash away the subassembly, help the circulation flow of adsorbent to and with the abundant contact of sewage, improve adsorption efficiency. Meanwhile, the two diversion scouring assemblies are matched with each other, have multiple scouring modes, are flexibly adjusted, and can achieve a better scouring effect.

Optionally, reflux unit includes top backward flow mouth, middle part backward flow mouth, bottom backward flow mouth, back flow and backwash pump, the top backward flow mouth is connected on the top of back flow, and bottom backward flow mouth is connected to the bottom, and the middle part backward flow mouth communicates the back flow through a branch pipe, the backwash pump is connected in the back flow to provide the required power of adsorbent fluidization.

Optionally, the reflux device further comprises an adsorbent reflux port, the adsorbent reflux port is communicated with the reflux pipe through a branch pipe, the bottom reflux port is arranged in the water inlet area, the adsorbent reflux port is arranged at the lower part of the fluidized adsorption area, and preferably, the adsorbent reflux port is arranged at the bottom of the fluidized adsorption area.

When the middle return port and the adsorbent return port are started, the return pipe can return the feed liquid and the adsorbent to the adsorbent return port from the middle return port together, and circulation of the adsorbent is promoted in an external circulation mode.

And the top return port, the middle return port, the bottom return port and the adsorbent return port are provided with valves for controlling the opening, closing and flow of each return port.

The reflux device of the utility model realizes different functions through different reflux ports by arranging reflux ports at different positions of the fluidization adsorption column, for example, the top reflux port is matched with the bottom reflux port to realize feed liquid reflux, and power required by adsorbent fluidization is provided; the middle part return port is matched with the bottom part return port, so that when the low liquid level occurs during the replacement of the adsorbent, the reflux is ensured, and the continuous operation is ensured; the middle part return port is matched with the adsorbent return port to realize the external circulation of the adsorbent. The application form of the reflux device is flexible and various, and different requirements of the fluidized adsorption device are met.

Optionally, the middle return port is provided with a switchable filter screen, the bottom return port is arranged in the water inlet area, and when the middle return port and the bottom return port are matched to replace the adsorbent, the filter screen is started to filter the adsorbent, and only the feed liquid flows back to the water inlet area; when the middle return port and the adsorbent return port are matched with the circulating adsorbent, the filter screen is closed, and the feed liquid and the adsorbent are refluxed to the bottom of the fluidized adsorption zone together.

Optionally, the height of the middle reflux port is 1/4-3/4 of the height of the fluidized adsorption zone. Preferably, the height of the central reflux port is from 1/4 to 1/2 of the height of the fluidized adsorption zone.

The utility model also provides a fluidization adsorption method, fluidization adsorption method uses above-mentioned fluidization adsorption equipment to accomplish, fluidization adsorption method includes following step:

(1) injecting an adsorbent into the fluidized adsorption zone through the feed inlet until the standing and stacking volume of the adsorbent accounts for 10% -90% of that of the fluidized adsorption zone; simultaneously, clear water is injected until the liquid level reaches a top reflux port;

(2) starting a reflux pump, a top reflux port and a bottom reflux port, refluxing clear water, and starting the fluidized adsorption column;

(3) pumping sewage into the fluidized adsorption column from the water inlet, and allowing the sewage to flow out from the water outlet after the sewage is adsorbed by the fluidized adsorption zone, so as to obtain produced water; meanwhile, the sewage washes the filtering component through the diversion scouring component to prevent the adsorbent from adhering;

(4) when the concentration of the pollutants is higher than a set target value or a water outlet discharge standard, replacing the adsorbent, closing the top reflux port, switching to the middle reflux port, discharging the adsorbent saturated in adsorption through the discharge port, closing the discharge port when the liquid level drops to the middle reflux port, and supplementing the adsorbent through the feed port;

(5) and when the liquid level reaches the top reflux port again, closing the middle reflux port and switching to the top reflux port again.

Optionally, the adsorbent is a powdery adsorbent or a granular adsorbent, and the particle size is 50 μm-2 mm.

Preferably, the adsorbent in step (1) has a static bulk of from 10% to 40% of the fluidized adsorption zone.

Optionally, the step (2) specifically includes: opening a reflux pump, adjusting valves of a top reflux port and a bottom reflux port, controlling the ascending flow velocity of the fluidized adsorption zone, and controlling the ascending flow velocity u (mm/s) to be 1.5-20 times of the initial fluidizing velocity of the used adsorbent; the initial fluidization velocity can be calculated by the following formula:

in the formula, mu_l、ρ_lRespectively, the viscosity (Pa s) and density (kg/m) of water³)，d_pIs the average particle size (m), R, of the adsorbent_ep-mfThe critical reynolds number for the adsorbent can be calculated by the following formula:

Re_p-mf＝(25.28²+0.0571Ar_p)^0.5-25.28

in the formula, A_rpArchimedes number for adsorbent:

in the formula, ρ_sIs the density (kg/m) of the adsorbent³) And g is the acceleration of gravity.

Optionally, the distance (D, mm) between the lower surface of the filter assembly and the top of the flow-guide flushing assembly in step (3) can be calculated by the following formula:

in the above formula, n is a multiple of the ascending flow velocity u relative to the initial fluidization velocity of the adsorbent, d'_pIs the average particle size (mm) of the adsorbent. In thatIn practical application, the small particle adsorbent corresponds to a larger n, and the large particle adsorbent corresponds to a smaller n.

The fluidized adsorption device and the fluidized adsorption method for sewage treatment are suitable for removing various pollutants, such as phosphate, fluoride ions, copper ions, zinc ions, lead ions, chromium ions, cadmium ions, nickel ions and the like.

Drawings

FIG. 1 is a schematic view of the structure of the fluidized adsorption apparatus of example 1.

FIG. 2 is a schematic view of the structure of the fluidized adsorption apparatus of example 7.

In the attached drawings, 1-water inlet area; 2-a fluidized adsorption zone; 3-water outlet zone; 4-water distribution plate; 5-a first diversion scouring assembly; 501-first flushing pipe; 502 — a first draft tube; 6, a movable filter screen; 7-a return pipe; 8-reflux pump; 9-a water inlet; 10-water outlet; 11-a feed inlet; 12-a discharge port; 13-top return port; 14-middle return port; 15-bottom reflux port; 16-a second diversion flushing component; 1601 — a second washout tube; 1602-a second draft tube; 17-adsorbent return port.

Detailed Description

Example 1

The fluidized adsorption device for sewage treatment of the embodiment, as shown in fig. 1, includes a fluidized adsorption column and a reflux device, the fluidized adsorption column is sequentially provided with a water outlet zone 3, a fluidized adsorption zone 2 and a water inlet zone 1 from top to bottom, the top end of the water inlet zone 1 is connected with the fluidized adsorption zone 2 through a water distribution plate 4, and the top end of the fluidized adsorption zone 2 is connected with the water outlet zone 3 through a filter assembly; reflux unit includes top backward flow mouth 13, middle part backward flow mouth 14, bottom backward flow mouth 15 and the back flow 7 of putting through three backward flow mouth, top backward flow mouth 13 is established at play pool 3, middle part backward flow mouth 14 is established at fluidization adsorption zone 2, bottom backward flow mouth 15 is established at intake zone 1, start top backward flow mouth 13 and bottom backward flow mouth 15 during absorption, start middle part backward flow mouth 14 and bottom backward flow mouth 15 when changing the adsorbent for fluidization adsorption column continuous operation.

The bottom of the water inlet area 1 is provided with a water inlet 9, the water outlet area 3 is provided with a water outlet 10, the water outlet 10 is positioned above the top reflux port 13, sewage enters from the bottom of the water inlet area and is discharged from the water outlet of the water outlet area after being adsorbed by the fluidized adsorption area, and the adsorption treatment is completed.

The fluidized adsorption zone 2 is provided with a feed inlet 11 and a discharge outlet 12, the discharge outlet 12 is positioned at the bottom of the fluidized adsorption zone 2 and above the water distribution plate 4, which is beneficial to discharge the adsorbent as much as possible and reduce the residue, the feed inlet 11 is positioned above the discharge outlet 12, and the feed rate and the discharge rate of the adsorbent are respectively controlled by valves.

The surface of the water distribution plate 4 is uniformly provided with through holes, the aperture of each through hole is smaller than the particle size of the adsorbent, the adsorbent is prevented from falling into the water inlet area 1, and meanwhile, the inlet water is uniformly distributed in the radial direction of the fluidized adsorption column after passing through the water distribution plate 4 and uniformly passes through the fluidized adsorption area 2.

The filter component is a movable filter screen 6, the aperture of the meshes of the movable filter screen 6 is smaller than the particle size of the adsorbent, and the adsorbent is intercepted below the movable filter screen 6 during fluidization movement, namely in the fluidization adsorption area 2 and cannot run off from the water outlet 10 along with the water body.

The upper surface of the movable filter screen 6 is provided with a driving rod, the driving rod is connected with a driving device outside the fluidization adsorption column, the driving rod drives the movable filter screen 6 to move up and down in the fluidization adsorption column, the height of the fluidization adsorption zone 2 is adjusted in real time, the size of the sewage inflow load or the fluctuation of the inflow condition in the operation process is adjusted in real time, the fluidization state of the adsorbent in the fluidization adsorption zone and the contact state of the sewage and the adsorbent are changed, the adsorption requirements under different working conditions are met, and the stable operation and the water outlet quality are ensured.

For example, the height ratio of the water inlet zone 1, the fluidized adsorption zone 2 and the water outlet zone 3 is 1:5:1, the height-diameter ratio of the fluidized adsorption zone 2 is 3.5:1, the axial cross section of the water inlet zone 1 is conical, and the internal angle of the cone is 60 degrees.

The below of portable filter screen 6 is equipped with first water conservancy diversion and erodees subassembly 5, and first water conservancy diversion erodees subassembly 5 includes first flushing pipe 501 and first honeycomb duct 502, and the bottom and the first honeycomb duct 502 intercommunication of first flushing pipe 501, first flushing pipe 501 are cylindricly, and first honeycomb duct 502 is the horn mouth shape, and the bottom opening is 45 with horizontal angle. The diameter of the first flushing pipe 501 is 1/5 of the fluidized adsorption zone 2, and the bottom opening radius of the first flow guide pipe 502 is 3/4 of the radius of the fluidized adsorption zone 2. The first diversion scouring component 5 is fixedly connected with the movable filter screen 6 and moves up and down along with the movable filter screen 6.

Reflux unit includes top backward flow mouth 13, middle part backward flow mouth 14, bottom backward flow mouth 15, back flow pipe 7 and backwash pump 8, and top backward flow mouth 13 is connected on the top of back flow pipe 7, and bottom backward flow mouth 15 is connected to the bottom, and middle part backward flow mouth 14 communicates back flow pipe 7 through a branch pipe, and backwash pump 8 is connected in back flow pipe 7 for partly backward flow the feed liquid of play water zone 3 or fluidization adsorption zone 2 into intake zone 1, so as to provide the required power of adsorbent fluidization. The height of the central reflux opening 14 is 1/4 the height of the fluidized adsorption zone 2.

The top return port 13 and the middle return port 14 are provided with valves for controlling the opening, closing and flow of each return port.

Example 2

In the fluidized adsorption device for wastewater treatment of this embodiment, the pipe diameter of the first flushing pipe 501 is 1/10 of the fluidized adsorption zone 2, and the bottom opening radius of the first flow guiding pipe 502 is 1/2 of the radius of the fluidized adsorption zone 2.

The other structure of the fluidized adsorption apparatus for wastewater treatment of this example was the same as that of example 1.

Example 3

In the fluidized adsorption device for wastewater treatment of this embodiment, the pipe diameter of the first flushing pipe 501 is 1/4 of the fluidized adsorption zone 2, and the bottom opening radius of the first flow guiding pipe 502 is 4/5 of the radius of the fluidized adsorption zone 2.

The other structure of the fluidized adsorption apparatus for wastewater treatment of this example was the same as that of example 1.

Example 4

In the fluidized adsorption device for sewage treatment of the embodiment, the height of the middle return opening is 1/2 of the height of the fluidized adsorption zone.

The other structure of the fluidized adsorption apparatus for wastewater treatment of this example was the same as that of example 1.

Example 5

In the fluidized adsorption device for sewage treatment of the embodiment, the height of the middle return opening is 3/4 of the height of the fluidized adsorption zone.

The other structure of the fluidized adsorption apparatus for wastewater treatment of this example was the same as that of example 1.

Example 6

In the fluidized adsorption device for sewage treatment of this embodiment, the heights of the water inlet zone 1, the fluidized adsorption zone 2 and the water outlet zone 3 are 0.33m, 1m and 0.267m, respectively, and the height ratio of the water inlet zone 1, the fluidized adsorption zone 2 and the water outlet zone 3 is 1:3: 0.8; the internal diameter of the fluidized adsorption zone 2 is 0.2m, the height-diameter ratio of the fluidized adsorption zone 2 is 5:1, the axial cross section of the water inlet zone 1 is conical, and the internal angle of the conical is 40 degrees. The first flow guide tube 502 is in the shape of a bell mouth, and the bottom opening forms an included angle of 30 degrees with the horizontal plane.

The other structure of the fluidized adsorption apparatus for wastewater treatment of this example was the same as that of example 1.

Example 7

The fluidization adsorption device for sewage treatment of this embodiment, as shown in fig. 2, first water conservancy diversion erodees subassembly 5 and portable filter screen 6 swing joint, and the actuating lever is the sleeve pipe mode, and the portable filter screen 6 of outer tube fixed connection, the subassembly 5 is erodeed to the first water conservancy diversion of inner tube fixed connection, and through the relative motion of inner tube and outer tube, the regulation of distance between subassembly 5 and the portable filter screen 6 is erodeed to the realization first water conservancy diversion to different demands to scour intensity when dealing with different fluidization speed. The diameter of the first flushing pipe 501 is 1/5 of the fluidized adsorption zone 2, and the bottom opening radius of the first flow guide pipe 502 is 3/4 of the radius of the fluidized adsorption zone 2.

This embodiment is equipped with second water conservancy diversion and erodees subassembly 16, and second scouring pipe 1601 is cylindric, and second honeycomb duct 1602 is half horn mouth shape, and half pipe wall of second honeycomb duct 1602 is parallel and on the collinear with second scouring pipe 1601 promptly, and half pipe wall is the horn mouth shape of outside extension, and this horn mouth is 45 with horizontal angle, and the lower edge of second honeycomb duct 1602 and second scouring pipe 1601 is on the coplanar. During the application, press close to fluidization adsorption zone 2 wall with the vertical one side of second honeycomb duct 1602, with the inside rivers region of the loudspeaker opening one side of second honeycomb duct 1602 towards fluidization adsorption zone 2, wash the regional movable filter screen 6 that is close to fluidization adsorption zone 2 wall.

Six second diversion scouring components 16 are arranged at positions close to the wall surface along the circumferential direction of the fluidized adsorption zone and are fixedly connected with the first diversion scouring components 15 through connecting rods to form a whole. The second diversion scouring assembly 16 and the first diversion scouring assembly 15 move up and down relative to the movable filter screen 6 through a sleeve type driving rod to adjust the relative distance between the diversion scouring assembly and the movable filter screen 6, and can also rotate relative to the movable filter screen 6 to adjust the position of the second diversion scouring assembly 16 corresponding to scouring of the edge of the movable filter screen 6.

The reflux device of the embodiment also comprises an adsorbent reflux port 17, and is communicated with the reflux pipe 7 through a branch pipe, and the adsorbent reflux port 17 is arranged at the bottom of the fluidized adsorption zone. The height of the central reflux opening 14 is 1/4 the height of the fluidized adsorption zone 2.

When the intermediate return port 14 and the adsorbent return port 17 are activated, the return pipe 7 can return the feed liquid and the adsorbent together from the intermediate return port 14 to the adsorbent return port 17, and promote the circulation of the adsorbent in an external circulation manner.

The middle return port 14 is provided with a switchable filter screen (not shown), when the middle return port 14 is matched with the bottom return port 15 to replace the adsorbent, the filter screen is started to filter the adsorbent, and only the feed liquid flows back to the water inlet area 1; when the middle return port 14 is matched with the adsorbent return port 17, the filter screen is closed, and the return pipe 7 can return the feed liquid and the adsorbent to the adsorbent return port 17 from the middle return port 14 and send the feed liquid and the adsorbent to the bottom of the fluidized adsorption zone 2, so that the circulation of the adsorbent is promoted in an external circulation mode.

The other structure of the fluidized adsorption apparatus for wastewater treatment of this example was the same as that of example 1.

Example 8

The fluidization adsorption device for sewage treatment in this embodiment does not have a diversion flushing component, and the other structures are the same as those in embodiment 1.

Example 9

The fluidized adsorption device for sewage treatment of the embodiment is not provided with an adsorbent return opening, and the other structures are the same as those of the embodiment 1.

Example 10

In the fluidized adsorption device for sewage treatment of the embodiment, the bottom reflux port is arranged at the bottom of the fluidized adsorption zone and is positioned below the adsorbent reflux port, and other structures are the same as those in embodiment 1.

Application example 1

The fluidized adsorption method provided by the application example uses the fluidized adsorption device of embodiment 1 for deep phosphorus removal for treating biochemical effluent of an urban sewage plant, and comprises the following steps:

(1) phosphorus removal adsorbent with average particle size of 50 μm is injected into fluidized adsorption zone 2 through feed port 11 until the standing bulk volume of the adsorbent accounts for 10% of that of fluidized adsorption zone 2; simultaneously, clear water is injected until the liquid level reaches the top return port 13;

(2) starting a reflux pump 8, adjusting valves of a top reflux port 13 and a bottom reflux port 15, refluxing clear water, controlling the rising flow rate of the fluidized adsorption zone 2, controlling the rising flow rate to be 20 times of the initial fluidizing speed of the used adsorbent, and starting the fluidized adsorption column; the initial fluidization velocity of the adsorbent is 0.069mm/s, and the ascending flow velocity is 1.38 mm/s;

(3) pumping sewage into the fluidized adsorption column from the water inlet 9, adsorbing the sewage by the fluidized adsorption zone 2, and then flowing out from the water outlet 10 to obtain produced water; meanwhile, the sewage washes the movable filter screen 6 through the first flow guide washing assembly 5 and the second flow guide washing assembly 16 to prevent the adhesion of the adsorbent;

(4) when the concentration of phosphate sampled from the water outlet 10 is higher than 0.5mg/L, replacing the adsorbent, closing the top return port 13, switching to the middle return port 14, discharging the adsorbent saturated in adsorption through the discharge port 12, closing the discharge port 12 when the liquid level drops to the middle return port 14, and supplementing the adsorbent through the feed port 11;

(5) when the liquid level reaches the top return port 13 again, the middle return port 14 is closed, the liquid level is switched to the top return port 13 again, and the adsorption treatment is continued;

(6) and (5) repeating the steps (1) to (5) until the sewage treatment is finished.

And (3) calculating the distance (D, mm) between the lower surface of the filter assembly and the top of the diversion scouring assembly according to the following formula:

application example 2

The fluidized adsorption method provided in this application example was the same as in example 10, and the fluidized adsorption apparatus of example 2 was used.

Application example 3

The fluidized adsorption method provided in this application example was the same as in example 10, and the fluidized adsorption apparatus of example 3 was used.

Application example 4

The fluidized adsorption method provided in this application example was the same as in example 10, and the fluidized adsorption apparatus of example 4 was used.

Application example 5

The fluidized adsorption method provided in this application example was the same as in example 10, and the fluidized adsorption apparatus of example 5 was used.

Application example 6

The fluidized adsorption method provided in this application example was the same as in example 10, and the fluidized adsorption apparatus of example 6 was used.

Application example 7

The fluidized adsorption method provided in this application example was the same as in example 10, and the fluidized adsorption apparatus of example 7 was used.

Application example 8

The fluidized adsorption method provided in this application example was the same as in example 10, and the fluidized adsorption apparatus of example 8 was used.

Application example 9

The fluidized adsorption method provided in this application example was the same as in example 10, and the fluidized adsorption apparatus of example 9 was used.

Comparative example 1

The fluidized adsorption method provided by the comparative example is the same as that of example 10, the fluidized adsorption device for sewage treatment of the comparative example is not provided with a reflux device, and the other structures are the same as those of example 1.

Application example 10

The fluidized adsorption method provided by the application example is used for deep fluorine removal of a fluorination plant by using the fluidized adsorption device of the embodiment 7, and comprises the following steps:

(1) injecting a phosphorus removal adsorbent with the average particle size of 2mm into the fluidized adsorption zone 2 through the feed inlet 11 until the standing and stacking volume of the adsorbent accounts for 40% of that of the fluidized adsorption zone 2; simultaneously, clear water is injected until the liquid level reaches the top return port 13;

(2) starting a reflux pump 8, adjusting valves of a top reflux port 13 and a bottom reflux port 15, refluxing clear water, controlling the rising flow rate of the fluidized adsorption zone 2 to be 1.5 times of the initial fluidizing speed of the used adsorbent, and starting the fluidized adsorption column; the initial fluidization velocity of the adsorbent is 14.22mm/s, and the ascending flow velocity is 21.33 mm/s;

(3) pumping sewage into the fluidized adsorption column from the water inlet 9, adsorbing the sewage by the fluidized adsorption zone 2, and then flowing out from the water outlet 10 to obtain produced water; meanwhile, the sewage washes the movable filter screen 6 through the first flow guide washing assembly 5 and the second flow guide washing assembly 16 to prevent the adhesion of the adsorbent;

(4) when the concentration of fluoride sampled at the water outlet 10 is higher than 6mg/L, replacing the adsorbent, closing the top return port 13, switching to the middle return port 14, discharging the adsorbent saturated in adsorption through the discharge port 12, closing the discharge port 12 when the liquid level drops to the middle return port 14, and supplementing the adsorbent through the feed port 11;

(5) when the liquid level reaches the top return port 13 again, the middle return port 14 is closed, the liquid level is switched to the top return port 13 again, and the adsorption treatment is continued;

(6) and (5) repeating the steps (1) to (5) until the sewage treatment is finished.

And (3) calculating the distance (D, mm) between the lower surface of the filter assembly and the top of the diversion scouring assembly according to the following formula:

TABLE 1 effects of treating wastewater of application examples 1 to 10

Note: the sewage treated by the application example 10 is fluorine-containing waste water.

According to the table, use the utility model provides a fluidization adsorption equipment and fluidization adsorption method can reach good treatment effect, and application example 1-9 handle phosphorus-containing waste water, and the phosphate clearance all stabilizes more than 99%, and the phosphate concentration of effluent all steadily is less than "town sewage treatment plant emission standard (GB 18918-. The fluoride removal rate of the fluorine-containing wastewater treated by the application example 10 is stabilized to be more than 99%, and the concentration of the fluoride in the effluent is stabilized to be lower than the emission limit value of inorganic chemical industry pollutant emission standard (GB 31573-2015) of 6.0 mg/L.

Claims (10)

1. A fluidized adsorption device for sewage treatment comprises a fluidized adsorption column and a reflux device, and is characterized in that the fluidized adsorption column is sequentially provided with a water outlet area, a fluidized adsorption area and a water inlet area from top to bottom, the top end of the water inlet area is connected with the fluidized adsorption area through a water distribution plate, and the top end of the fluidized adsorption area is connected with the water outlet area through a filter component;

reflux unit includes top backward flow mouth, middle part backward flow mouth, bottom backward flow mouth and switches on the back flow of three backward flow mouth, and the top backward flow mouth is established at the play basin, and the middle part backward flow mouth is established at fluidization adsorption zone, and the bottom backward flow mouth is established at intake zone or fluidization adsorption zone, launches top backward flow mouth and bottom backward flow mouth during absorption, launches middle part backward flow mouth and bottom backward flow mouth during the change adsorbent for fluidization adsorption column continuous operation.

2. The fluidized adsorption device of claim 1, wherein the filter assembly is a movable filter screen having a mesh opening size smaller than the adsorbent particle size;

the upper surface of the movable filter screen is provided with a driving rod which is connected with a driving device outside the fluidization adsorption column, and the driving rod drives the movable filter screen to move up and down inside the fluidization adsorption column to adjust the height of the fluidization adsorption zone in real time.

3. The fluidized adsorption device of claim 2, wherein a flow guide scouring assembly is arranged below the filtering assembly, the flow guide scouring assembly comprises a scouring pipe and a flow guide pipe, the bottom of the scouring pipe is communicated with the flow guide pipe, the scouring pipe is cylindrical, and the flow guide pipe is in a bell mouth shape;

the pipe diameter of the flushing pipe is 1/10-1/4 of the inner diameter of the fluidized adsorption zone, and the opening radius of the bottom of the draft tube is 1/2-4/5 of the radius of the fluidized adsorption zone.

4. The fluidized adsorption device of claim 3, wherein the diversion scouring assembly is movably connected with the filtering assembly, the driving rod is in a sleeve mode, the outer pipe is fixedly connected with the filtering assembly, the inner pipe is fixedly connected with the diversion scouring assembly, and the distance between the diversion scouring assembly and the filtering assembly can be adjusted by the relative movement of the inner pipe and the outer pipe so as to meet different requirements on scouring strength at different fluidizing speeds.

5. The fluidized adsorption unit of claim 4, wherein the flow directing and flushing assembly has a second configuration, wherein the flushing pipe is cylindrical, the flow directing pipe is semi-bell-mouthed, one half of the wall of the flow directing pipe is parallel and collinear with the flushing pipe, the other half of the wall of the flow directing pipe is outwardly flared, and the lower edge of the flow directing pipe is in the same plane;

the flow guide scouring assemblies of the half horn mouths are arranged at positions close to the wall surface along the circumferential direction of the fluidized adsorption zone and are fixedly connected with the flow guide scouring assemblies through connecting rods so as to form a whole and move along with the filtering assemblies.

6. The fluidized adsorption unit of claim 5, wherein the semi-flared flow-guide scouring assembly moves up and down relative to the filter assembly to adjust the relative distance between the semi-flared flow-guide scouring assembly and the filter assembly; alternatively, the first and second electrodes may be,

the diversion scouring assembly of the half-bell mouth rotates relative to the filtering assembly so as to adjust the position of the diversion scouring assembly of the half-bell mouth, which correspondingly scours the edge of the filtering assembly.

7. The fluidized adsorption device of claim 2, wherein the reflux device comprises a top reflux port, a middle reflux port, a bottom reflux port, a reflux pipe and a reflux pump, the top reflux port is connected to the top end of the reflux pipe, the bottom reflux port is connected to the bottom end of the reflux pipe, the middle reflux port is communicated with the reflux pipe through a branch pipe, and the reflux pump is connected to the reflux pipe to provide power for fluidization of the adsorbent.

8. The fluidized adsorption unit of claim 7, wherein the return means further comprises an adsorbent return port and is connected to the return conduit via a branch conduit, the bottom return port is disposed in the water inlet zone, and the adsorbent return port is disposed at a lower portion of the fluidized adsorption zone;

when the middle return port and the adsorbent return port are started, the return pipe can return the feed liquid and the adsorbent to the adsorbent return port from the middle return port together, and circulation of the adsorbent is promoted in an external circulation mode.

9. The fluidized adsorption device of claim 8, wherein the height of the central reflux port is from 1/4 to 3/4 of the fluidized adsorption zone height;

the middle part return opening is provided with a switchable filter screen, when the middle part return opening is matched with the bottom return opening to replace the adsorbent, the filter screen is started to filter the adsorbent, and only the feed liquid flows back to the water inlet area; when the middle return port and the adsorbent return port are matched with the circulating adsorbent, the filter screen is closed, and the feed liquid and the adsorbent are refluxed to the bottom of the fluidized adsorption zone together.

10. The fluidized adsorption unit of claim 1, wherein the water inlet zone has a water inlet at the bottom and the water outlet zone has a water outlet above the top return port;

the fluidized adsorption zone is provided with a feed inlet and a discharge outlet, the feed inlet is positioned above the discharge outlet, and the feed rate and the discharge rate of the adsorbent are respectively controlled by a valve;

the surface of the water distribution plate is uniformly provided with through holes, the aperture of each through hole is smaller than the particle size of the adsorbent, and the adsorbent is prevented from falling into a water inlet area.

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