CN212713181U - Organic wastewater treatment system based on biological nest - Google Patents

Abstract

The utility model discloses an organic wastewater treatment system based on biological nest, this system includes: a grid water collecting tank, a pre-aeration water distribution adjusting tank, an inclined tube primary sedimentation tank, a hydrolysis acidification tank, a super-effect ion shallow air flotation tank, a biochemical anoxic tank, a contact aerobic tank, a delayed contact oxidation tank, a high-efficiency sedimentation tank, a filtering tank and a discharge gathering tank which are communicated in sequence; the hydrolysis acidification tank, the contact aerobic tank and the time-delay contact oxidation tank are filled with organic biological nest fillers, each organic biological nest filler consists of a support framework and non-woven fabrics wrapped on the periphery of the support framework, each support framework consists of a suspended ball or spherical bamboo strip, the diameter of each support framework is phi 25-phi 200mm, and water through holes are formed in the non-woven fabrics. The utility model discloses with the coupling of organic biological nest filler in organic wastewater treatment system, the processing system who obtains not only can effectively get rid of organic pollutant, sulphide, the colourity that difficult decomposition and molecular weight are big, has splendid effect to nitrogen and phosphorus removal, difficult degradation antibiotic etc. moreover.

Description

Organic wastewater treatment system based on biological nest

Technical Field

The utility model relates to an organic wastewater treatment technical field especially relates to an organic wastewater treatment system based on biological nest.

Background

The biological nest is also called biological nest, and is a nest where microorganisms like rest, live and multiply. In the sewage treatment project, each activated sludge is a biological nest which is the most primitive and smallest biological nest in nature.

Activated sludge technology has been introduced for nearly a hundred years to treat municipal sewage and has been used to date. The technology has wide application, is a mature sewage treatment process, and achieves great effect in the treatment engineering of urban domestic sewage. However, many deficiencies of the activated sludge process have been observed in long-term wastewater treatment practices, such as: the sludge is easy to expand and bubble, and the sludge is easy to lose; the sludge amount is relatively small; the labor intensity is high, and the daily management requirements are more careful and complicated; the activated sludge process can only treat organic sewage with high BOD/COD ratio and low wastewater concentration, such as domestic wastewater with low CODcr. When the activated sludge technology is used for treating organic wastewater which is difficult to decompose and has large molecular weight, the treatment effect is not ideal. The reason is that the active sludge has fine particles, relatively low sludge index, high water content of the sludge and small corresponding total amount of microorganisms; meanwhile, the activated sludge process can only aerobically digest low-molecular and easily-decomposable organic matters in an aeration tank, or partially hydrolyze and acidify organic matters with a larger molecular weight in an anaerobic tank. The activated sludge process can not be like some fillers in a contact oxidation pond, especially a biological nest with larger volume, can combine a large amount of various aerobic, anoxic and anaerobic bacterial communities, and can carry out repeated aerobic, anoxic and anaerobic biochemical reactions in cooperation in the same filler, so that various easily-treated and difficultly-decomposed organic matters and organic sludge with large molecular weight, even corpses of microorganisms, can be thoroughly decomposed, and the water quality is recovered to be clean.

The flow separation speed is the phenomenon that solid particles and colloid particles in natural fluid are quickly separated and gathered from the flow state with high flow speed to the area with low flow speed under a certain flow state environment condition, so that the cleanness of the fluid is achieved. According to the principle of separation speed in nature, organic or inorganic hydrophilic light, porous and coarse matrixes with large specific surface area are selected and are combined into a spheroid filler through screening and special processing. The fillers can play roles in blocking and dispersing flow states, so that a phenomenon that a high flow velocity area is arranged outside the ball and a plurality of low flow velocity areas are generated in the ball is caused; the flow speed difference achieves the effect of flow separation and rapid separation, and promotes pollutants, particles, organic colloids and the like in the fluid to be separated and gathered at the periphery of the sphere and in the sphere. It is called a "flow off ball". The free flowing ball can also gather a large amount of microorganisms, and the microorganisms are willing to reproduce, decompose and digest various organic matters and clean water. The flow-off ball is a biological ball-biological nest.

At present, the number of treatment systems for treating organic wastewater by using biological nests is small, and especially, the number of systems for treating printing and dyeing wastewater is small, so that the organic wastewater treatment system by using biological nests is needed.

SUMMERY OF THE UTILITY MODEL

The utility model provides an organic wastewater treatment system based on biological nest, this system can effectively handle the organic waste water that difficult decomposition and molecular weight are big, improves nitrogen and phosphorus removal effect.

The specific technical scheme is as follows:

a biological nest-based organic wastewater treatment system comprising: a grid water collecting tank, a pre-aeration water distribution adjusting tank, an inclined tube primary sedimentation tank, a hydrolysis acidification tank, a super-effect ion shallow air flotation tank, a biochemical anoxic tank, a contact aerobic tank, a delayed contact oxidation tank, a high-efficiency sedimentation tank, a filtering tank and a discharge gathering tank which are communicated in sequence;

organic biological nest fillers are filled in the hydrolysis acidification tank, the contact aerobic tank and the delayed contact oxidation tank; the organic biological nest filler consists of a support framework and non-woven fabrics wrapped on the periphery of the support framework, the support framework is composed of suspended balls or spherical bamboo splits, the diameter of the support framework is phi 25-phi 200mm, and the non-woven fabrics are provided with water through holes for sewage to flow in and out.

Organic biological nest filler use traditional polypropylene materials to mould plastics the suspension ball filler or the spherical thin bamboo strips used for weaving that form as the braced frame, outsourcing non-woven fabrics to the main carrier that the biomembrane grows is regarded as to the non-woven fabrics. In an aeration tank for sewage treatment, water holes are reserved on non-woven fabrics, so that sewage inside and outside the organic biological nest filler is communicated through the holes, the outer surface of the organic biological nest filler is contacted with oxygen supply of the aeration tank to form an aerobic biomembrane, and the inner surface of the organic biological nest filler is not directly contacted with oxygen to form an anoxic biomembrane. Sewage in the organic biological nest filler is treated under an anoxic or anaerobic condition, sewage outside the organic biological nest filler is treated under an aerobic condition, and the sewage on the inner side and the sewage on the outer side are freely alternated through holes reserved in the woven fabric due to concentration gradient difference to form anoxic-aerobic alternative treatment. In addition, the utility model discloses still control oxygen deficiency, the volume of good oxygen in the sewage pond through the packing proportion and the skeleton diameter size of adjustment organic biological nest filler to reach fine nitrogen and phosphorus removal effect.

Furthermore, the hydrolysis acidification tank is divided into three stages of hydrolysis acidification areas which are communicated in sequence through partition plates; the bottom of the first-stage hydrolysis acidification area is communicated with the upper part of the inclined tube primary sedimentation tank through a pipeline, the upper part of the second-stage hydrolysis acidification area is communicated with the upper part of the first-stage hydrolysis acidification area, and the bottom of the third-stage hydrolysis acidification area is communicated with the bottom of the second-stage hydrolysis acidification area; the bottom of each stage of hydrolysis acidification zone is provided with a perforated aeration pipe, a bearing layer is arranged on the perforated aeration pipe, and organic biological nest filler is accumulated on the bearing layer.

Furthermore, the framework diameter of the organic biological nest filler filled in the first-stage hydrolytic acidification zone is 15 mm-10 cm, and the filling rate is 15% -100%; the framework diameter of the organic biological nest filler filled in the secondary hydrolytic acidification zone is 30 mm-10 cm, and the filling rate is 30% -100%; the framework diameter of the organic biological nest filler filled in the third-stage hydrolytic acidification zone is 30 mm-15 cm, and the filling rate is 30% -100%.

Further, the contact aerobic tank consists of two stages of aerobic tanks; the upper part of the first-stage aerobic tank is communicated with the biochemical anoxic tank, and the bottom of the second-stage aerobic tank is communicated with the first-stage aerobic tank; organic biological nest fillers are filled in each stage of aerobic tanks.

Furthermore, an upper group of oxygen reaction zones and a lower group of oxygen reaction zones are arranged in the primary aerobic tank, the upper group of oxygen reaction zones and the lower group of oxygen reaction zones are respectively a first oxygen reaction zone and a second oxygen reaction zone from top to bottom, organic biological nest filler with the skeleton diameter of 30 mm-10 cm is filled in the first oxygen reaction zone, the filling rate is 15% -50%, organic biological nest filler with the skeleton diameter of 30 mm-15 cm is filled in the second oxygen reaction zone, and the filling rate is 15% -50%; each group of oxygen reaction zones sequentially comprises a perforated aeration pipe, a supporting layer and organic biological nest filler from bottom to top;

the secondary aerobic tank is sequentially provided with a perforated aeration pipe, a supporting layer and organic biological nest filler from bottom to top, the framework diameter of the organic biological nest filler in the secondary aerobic tank is 30 mm-15 cm, and the filling rate is 30% -100%;

furthermore, a perforated aeration pipe, a supporting layer and inorganic biological nest filler are sequentially arranged in the delayed contact oxidation pond from bottom to top; the inorganic biological nest filler is formed by mixing 5-30 mm volcanic rocks and 5-10 mm coal cinder according to the proportion of 1:1, and the filling rate is 30-100%.

Furthermore, a double-layer horizontally arranged fine grid is arranged in the grid water collecting tank, and the gap of the fine grid is 2-4 mm; the bottom of the pre-aeration water distribution regulating tank is provided with a water distribution pipeline, and a perforated aeration pipe is arranged above the water distribution pipeline; and a sludge collecting ditch and a sludge discharge pipe are arranged at the bottom of the inclined pipe primary sedimentation tank.

The utility model discloses in an organic wastewater treatment system based on biological nest with the coupling of organic biological nest filler, the skeleton is moulded plastics into with materials that have corrosion resistance, temperature resistance, ageing-resistant such as polypropylene (pp), high density polyethylene to organic biological nest filler, and the outer packing non-woven fabrics etc. can load the biomembrane carrier, and the through-hole that allies oneself with inside and outside (crossing the water hole promptly) is reserved to every independent organic biological nest filler monomer, forms the organic biological carrier filler that has high-efficient quality of water purification ability. The organic biological nest filler is arranged in the hydrolytic acidification tank and the anoxic tank, the outside of the organic biological nest filler is in an anoxic state, the inside of the organic biological nest filler is in an anaerobic state, and sewage on the inner side and the outer side freely alternates by reserving an inner-outer connection through hole due to the concentration gradient difference to form an anaerobic-anoxic alternate treatment condition; the organic biological nest filler is arranged in the aerobic tank, the outside of the organic biological nest filler is in an aerobic state, the inside of the organic biological nest filler is in an anoxic state, and sewage on the inner side and the outer side freely alternates by reserving the inner-outer connection through holes due to the concentration gradient difference to form an anoxic-aerobic alternate treatment condition. Therefore, the biological nest filler forms micro biological reaction individuals with different volumes and sizes, can effectively remove organic pollutants, sulfides and chromaticity which are difficult to decompose and have large molecular weight, and has excellent effects on nitrogen and phosphorus removal, difficult-to-degrade antibiotics and the like.

Compared with the prior art, the utility model discloses following beneficial effect has:

the utility model discloses with the coupling of organic biological nest filler in the organic wastewater treatment system who is giving first place to with "hydrolytic acidification + super effect ion shallow air supporting + biochemical oxygen deficiency + contact good oxygen + time delay contact oxidation", the processing system who obtains not only can effectively get rid of the organic pollutant, sulphide, the colourity that difficult decomposition and molecular weight are big, has splendid effect to nitrogen and phosphorus removal, difficult degradation antibiotic etc. moreover.

Drawings

FIG. 1 is a process flow diagram of the organic wastewater treatment system of the present invention.

Fig. 2 is a schematic structural diagram of the hydrolysis-acidification tank 4 in the organic wastewater treatment system of the utility model.

FIG. 3 is a schematic view of the structure of the aerobic contact tank 7 in the organic wastewater treatment system of the present invention.

FIG. 4 is a schematic diagram of the organic biological nest filling structure in the organic wastewater treatment system of the present invention.

Detailed Description

The present invention will be further described with reference to specific embodiments, which are only listed below, but the scope of the present invention is not limited thereto.

Example 1

As shown in figure 1, the utility model provides an organic wastewater treatment system based on biological nest, especially adapted for printing and dyeing wastewater, this system is including communicating in proper order: the system comprises a grid water collecting tank 1, a pre-aeration water distribution adjusting tank 2, an inclined tube primary sedimentation tank 3, a hydrolysis acidification tank 4, a super-effect ion shallow air flotation 5, a biochemical anoxic tank 6, a contact aerobic tank 7, a time-delay contact oxidation tank 8, a high-efficiency sedimentation tank 9, a filter tank 10 and a discharge collection tank 11.

Wherein, the hydrolysis acidification tank 4, the biochemical anoxic tank 6, the contact aerobic tank 7 and the time-delay contact oxidation tank 8 are all filled with organic biological nest filler, the organic biological nest filler consists of a support framework 12 and non-woven fabrics 13 wrapping the periphery of the support framework 12, the support framework 12 consists of suspended balls or spherical bamboo splits, the diameter is phi 25-phi 200mm, and the non-woven fabrics 13 are provided with a water through hole 14 for sewage to flow in and out.

The inside of grid catch basin 1 is equipped with the fine grid that double-deck plane set up, and the gap of fine grid is 3mm, can get rid of matters such as impurity and fine hair in the printing and dyeing wastewater. The top of the grid water collecting tank 1 is communicated with a drainage pipeline of printing and dyeing wastewater generated during production and processing in a textile mill or a printing and dyeing mill, and the bottom of the grid water collecting tank is communicated with the pre-aeration water regulating tank 2 through a pipeline. The bottom of the pre-exposure water distribution regulating tank 2 is provided with a water distribution pipeline communicated with the grid water collecting tank 1 for distributing the printing and dyeing wastewater entering the pre-exposure water distribution regulating tank; the perforated aeration pipe is arranged above the water distribution pipeline, and pre-aeration is carried out on the printing and dyeing wastewater to eliminate partial easily-decomposed pollutants. The inside of the inclined tube primary sedimentation tank 3 is provided with a hexagonal inclined tube, which is helpful for the sedimentation of sludge, and the bottom of the inclined tube primary sedimentation tank is provided with a sludge collecting ditch and a perforated sludge discharge pipe for sludge discharge.

The inside of the hydrolysis acidification tank 4 is divided into three areas which are communicated in sequence through partition boards, and the three areas are arranged into three levels, namely a first-level hydrolysis acidification area 41, a second-level hydrolysis acidification area 42 and a third-level hydrolysis acidification area 43. The bottom of the first-stage hydrolysis acidification zone 41 is communicated with the upper part of the inclined tube primary sedimentation tank 3 through a pipeline, the upper part of the second-stage hydrolysis acidification zone 42 is communicated with the upper part of the first-stage hydrolysis acidification zone 41, and the bottom of the third-stage hydrolysis acidification zone 43 is communicated with the bottom of the second-stage hydrolysis acidification zone 42. The bottom of each stage of hydrolysis acidification zone is provided with a perforated aeration pipe 44, a supporting layer 45 is arranged on the perforated aeration pipe 44, and organic biological nest filler 46 is accumulated on the supporting layer 45. Wherein the framework diameter of the organic biological nest filler filled in the first-stage hydrolytic acidification zone is 5cm, and the filling rate is 75 percent; the framework diameter of the organic biological nest filler filled in the secondary hydrolytic acidification zone is 7cm, and the filling rate is 75%; the framework diameter of the organic biological nest filler filled in the three-stage hydrolytic acidification zone is 10cm, and the filling rate is 90 percent

The super-efficient ion shallow air flotation tank 5 adopts an overhead materialization reaction and an overhead shallow air flotation tank, so that slag is convenient to discharge, and one-time lifting, conveying and water distribution are convenient to carry out. An aerobic return pipeline is arranged in the biochemical anoxic tank 6, and biochemical anoxic reaction is carried out through free oxygen molecules carried by return liquid. The super-effect ion shallow air flotation tank 5 is respectively communicated with the upper part of the third-stage hydrolysis acidification zone 43 of the hydrolysis acidification tank 4 and the biochemical anoxic tank 6.

The contact aerobic tank 7 consists of two stages of aerobic tanks; the upper part of the primary aerobic tank 71 is communicated with the biochemical anoxic tank 6, and the bottom of the secondary aerobic tank 72 is communicated with the primary aerobic tank 71; organic biological nest fillers are filled in each stage of aerobic tanks.

Wherein, an upper group of oxygen reaction zones and a lower group of oxygen reaction zones are arranged in the primary aerobic tank, the first oxygen reaction zone 711 and the second oxygen reaction zone 712 are respectively arranged from top to bottom, the organic biological nest filler with the skeleton diameter of 6cm is filled in the first oxygen reaction zone 711, the filling rate is 30 percent, the organic biological nest filler with the skeleton diameter of 10cm is filled in the second oxygen reaction zone 712, and the filling rate is 40 percent; each group of oxygen reaction zones sequentially comprises a perforated aeration pipe 74, a supporting layer 75 and organic biological nest filler 76 from bottom to top. The second-stage aerobic tank 72 is internally provided with a perforated aeration pipe, a supporting layer and organic biological nest filler from bottom to top in sequence, the framework diameter of the organic biological nest filler in the second-stage aerobic tank is 10cm, and the filling rate is 80%.

The inside of the delayed contact oxidation tank 8 is sequentially provided with a perforated aeration pipe, a bearing layer and inorganic biological nest filler from bottom to top; the inorganic biological nest filler is formed by mixing volcanic rock and coal cinder filler; wherein the particle size of the volcanic rock is 3cm, the particle size of the coal cinder is 15mm, and the mass ratio of the volcanic rock to the coal cinder is 1:1 percent and the filling rate is 80 percent. The delayed contact oxidation tank 8 is respectively communicated with the contact aerobic tank 7 and the high-efficiency sedimentation tank 9.

A PAC coagulant and a polyacrylamide flocculant are added into the high-efficiency sedimentation tank 9; the high-efficiency sedimentation tank 9 is communicated with a filtering tank 10, and the filtering tank 10 is communicated with a discharge collection tank 11.

Application example 1

The application example takes printing and dyeing wastewater of a certain printing and dyeing mill in Jiangsu as an example, and provides a method for treating printing and dyeing wastewater by using the organic wastewater treatment system, and the quality of raw water is as follows: CODcr is 1800-3500mg/L, PH value 9-12, chroma is 200-1000 times, sulfide is 2-20 mg/L; PVA (polyvinyl alcohol), purified enzyme, BOD: COD is as low as about 0.2, and biochemical treatment is difficult.

The specific treatment steps are as follows:

(1) introducing the printing and dyeing wastewater into a grid water collecting tank, a pre-aeration water distribution regulating tank and an inclined tube primary settling tank in sequence for pretreatment; the hydraulic retention time of the grid water collecting tank is controlled to be 15min, the hydraulic retention time of the pre-aeration water distribution adjusting tank is 12h, the hydraulic retention time of the inclined tube primary settling tank is 8h, and the filling rate of the hexagonal inclined tubes is 50%.

(2) Introducing the effluent obtained in the step (1) into a hydrolysis acidification tank for hydrolysis acidification treatment; controlling the hydraulic retention time of the hydrolysis acidification tank to be 48 h.

(3) And (3) introducing the effluent obtained in the step (2) into a super-effect ion shallow air flotation tank for solid-liquid separation, wherein the hydraulic retention time is 30min, and the concentration of suspended solid in the effluent is controlled below 30 mg/L.

(4) Introducing the effluent obtained in the step (3) into a biochemical anoxic tank for primary anoxic treatment; controlling the hydraulic retention time of the biochemical anoxic tank to be 4 h.

(5) Introducing the effluent obtained in the step (4) into a contact aerobic tank for alternate aerobic and anoxic treatment; controlling the hydraulic retention time of the contact aerobic tank to be 24h, and controlling the aeration gas-water ratio to be 15: 1.

(6) introducing the effluent water obtained in the step (5) into a delayed contact oxidation tank for secondary anoxic treatment; controlling the hydraulic retention time of the delay contact aerobic tank to be 1.5h, and controlling the aeration gas-water ratio to be 3: 1.

(7) introducing the effluent water obtained in the step (6) into a high-efficiency sedimentation tank and a filtering tank in sequence, and carrying out sedimentation and filtering treatment; the surface load of the high-efficiency sedimentation tank is controlled to be between 2.0 and 2.5 m/h.

(8) And (4) introducing the effluent obtained in the step (7) into a discharge collecting pool to obtain effluent.

The effluent quality is measured as follows: the chroma is basically reduced, the pH value is reduced to 6-7 from 9-12, the CODcr is reduced to less than 100mg/L from 1800-3500mg/L, and the pollutants which are difficult to be biodegraded, such as sulfide, PVA, refining enzyme, and the like are not detected, thereby reaching the discharge standard of pollutants for textile dyeing and finishing industrial water (GB 4287-2016).

Claims (6)

1. A biological nest-based organic wastewater treatment system, comprising: a grid water collecting tank, a pre-aeration water distribution adjusting tank, an inclined tube primary sedimentation tank, a hydrolysis acidification tank, a super-effect ion shallow air flotation tank, a biochemical anoxic tank, a contact aerobic tank, a delayed contact oxidation tank, a high-efficiency sedimentation tank, a filtering tank and a discharge gathering tank which are communicated in sequence;

organic biological nest fillers are filled in the hydrolysis acidification tank, the contact aerobic tank and the delayed contact oxidation tank; the organic biological nest filler consists of a support framework and non-woven fabrics wrapped on the periphery of the support framework, the support framework is composed of suspended balls or spherical bamboo splits, the diameter of the support framework is phi 25-phi 200mm, and the non-woven fabrics are provided with water through holes for sewage to flow in and out.

2. The biological nest based organic wastewater treatment system as claimed in claim 1, wherein the hydrolytic acidification tank is divided into three stages of hydrolytic acidification zones which are communicated in sequence by partition boards; the bottom of the first-stage hydrolysis acidification area is communicated with the upper part of the inclined tube primary sedimentation tank through a pipeline, the upper part of the second-stage hydrolysis acidification area is communicated with the upper part of the first-stage hydrolysis acidification area, and the bottom of the third-stage hydrolysis acidification area is communicated with the bottom of the second-stage hydrolysis acidification area; the bottom of each stage of hydrolysis acidification zone is provided with a perforated aeration pipe, a bearing layer is arranged on the perforated aeration pipe, and organic biological nest filler is accumulated on the bearing layer.

3. The biological nest-based organic wastewater treatment system as claimed in claim 2, wherein the framework diameter of the organic biological nest filler filled in the primary hydrolytic acidification zone is 15 mm-10 cm, and the filling rate is 15% -100%; the framework diameter of the organic biological nest filler filled in the secondary hydrolytic acidification zone is 30 mm-10 cm, and the filling rate is 30% -100%; the framework diameter of the organic biological nest filler filled in the third-stage hydrolytic acidification zone is 30 mm-15 cm, and the filling rate is 30% -100%.

4. The biological nest based organic wastewater treatment system of claim 1, wherein the contact aerobic tank consists of two stages of aerobic tanks; the upper part of the first-stage aerobic tank is communicated with the biochemical anoxic tank, and the bottom of the second-stage aerobic tank is communicated with the first-stage aerobic tank; organic biological nest fillers are filled in each stage of aerobic tanks.

5. The biological nest-based organic wastewater treatment system as claimed in claim 1, wherein the primary aerobic tank is provided with an upper group of oxygen reaction zones and a lower group of oxygen reaction zones, the upper group of oxygen reaction zones and the lower group of oxygen reaction zones are respectively a first oxygen reaction zone and a second oxygen reaction zone from top to bottom, the first oxygen reaction zone is filled with organic biological nest filler with the framework diameter of 30 mm-10 cm, the filling rate is 15% -50%, the second oxygen reaction zone is filled with organic biological nest filler with the framework diameter of 30 mm-15 cm, and the filling rate is 15% -50%; each group of oxygen reaction zones sequentially comprises a perforated aeration pipe, a supporting layer and organic biological nest filler from bottom to top;

the secondary aerobic tank is sequentially provided with a perforated aeration pipe, a supporting layer and organic biological nest filler from bottom to top, the framework diameter of the organic biological nest filler in the secondary aerobic tank is 30 mm-15 cm, and the filling rate is 30% -100%.

6. The biological nest-based organic wastewater treatment system as claimed in claim 1, wherein the grid catch basin is internally provided with double-layer horizontally arranged fine grids, and gaps of the fine grids are 2-4 mm; the bottom of the pre-aeration water distribution regulating tank is provided with a water distribution pipeline, and a perforated aeration pipe is arranged above the water distribution pipeline; and a sludge collecting ditch and a sludge discharge pipe are arranged at the bottom of the inclined pipe primary sedimentation tank.

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