KR101086158B1 - the final settling chamber with a dephosphorization part - Google Patents

Abstract

     The present invention relates to a final sedimentation tank which allows the sludge contained in the final treated water of wastewater or sewage to be sedimented and discharged, and in particular, to remove nutrients through the advanced biological treatment of wastewater or sewage. In this case, the phosphorus (P) remaining in the final treated water can be removed in an eco-friendly, efficient and economic manner.

To this end, the present invention provides a final sedimentation tank having a function of removing phosphorus by the crystallization dephosphorization method by integrally forming a dephosphorization part composed of a shell filter layer by accommodating shells that are currently discarded as marine wastes, thereby reducing waste and recycling. The aim is to make wastewater and sewage more economical with maintenance costs.

Shell, sedimentation tank, dephosphorization

Description

The final settling chamber with a dephosphorization part

The present invention is to precipitate the sludge contained in the waste water or the final treated water of sewage

It relates to the final sedimentation tank which can be discharged after discharge. Especially, if the wastewater or sewage can be removed through intensive biological treatment, it can be eco-friendly and efficient It can be economically removed.

In recent years, wastewater and sewage contain a large amount of nitrogen and phosphorus, which cause eutrophication of rivers by the use of pesticides and fertilizers in farmhouses and synthetic detergents at home. N) and phosphorus (P) are to be treated through advanced biological treatment process.

However, most of the nitrogen is removed by denitrification in the biological advanced treatment process, but in the case of phosphorus it is difficult to remove more than 30%.

Therefore, in order to remove nitrogen and phosphorus through advanced biological treatment, a chemical (coagulant) is added to the treated water through the bioreactor to add and remove the physicochemical treatment process to cause coagulation and precipitation.

However, in this case, the coagulation sediment removal method of phosphorus using the chemicals is not only a large amount of chemicals used, but also a large amount of sludge composed of aggregates.

Therefore, there is a problem in that a large amount of chemical consumption and sludge treatment costs are required, and thus, a considerable cost is required for maintenance and management, and a large amount of sludge due to aggregates increases the installation cost of the facility by additionally providing a separate flocculation / sedimentation tank. There is a burden.

Therefore, in the present invention, shells such as oysters and shellfish generated in aquaculture are now discarded as marine waste, but these shells have recently been studied to remove phosphorus (P) from waste and sewage. The aim is to provide a final settling tank that can remove phosphorus by the crystallization dephosphorization method so that waste and sewage can be treated more economically with low recycling cost as well as recycling of waste.

In addition, the dephosphorization material is to be stored so that the movement to the regeneration tank can be made easily and conveniently to be made semi-permanent use easily and conveniently according to the repeated use several times.

In addition, by using the final sedimentation tank to be able to more efficiently treat waste, sewage is to improve the water quality of the effluent more stably.

To this end, the present invention is to form a dephosphorization unit consisting of a shell filter layer by storing the shell in the existing final sedimentation tank, the shell is accommodated in the dephosphorization portion to form a filter box of the network structure to form a filter layer, The filter box is configured to form a lifting means for lifting by lifting to the open upper side of the dephosphorization portion using a hoist.

Therefore, the final sedimentation tank of the present invention is a dephosphorization part consisting of a shell filter layer using the shell as a dephosphorization material, and the phosphorus (P) contained in the treated water is not separated even through advanced biological treatment. It can be removed excellently by crystallization without going through a chemical treatment process.

In addition, since the removal of phosphorus (P) by the crystallization dephosphorization method can be treated semi-permanently without producing sludge, in addition to the recycling of the waste by using the shell, when the conventional chemical / chemical treatment using chemicals The cost of the drug was not required at all, as well as to reduce the sludge generated by the flocculation, thereby significantly reducing the treatment cost of the concentrated sludge.

Therefore, the initial system installation cost for waste and sewage treatment, as well as the low maintenance cost, enable more efficient, economical and stable discharged water quality.

Hereinafter, the most preferred embodiment of the present invention will be described with reference to the accompanying drawings.

As shown in Figures 1 to 4 the present invention is the sludge remaining in the treated water by flowing through the inlet portion 11 of the main body 10 to the treated water treated through the biological advanced treatment of waste. It is settled in the hopper part 14 of the lower part of 10, and it can remove through the sludge outflow part 12, and the supernatant water is comprised so that it can discharge through the outflow part 13 formed in the upper side of the main body 10. In the known final sedimentation tank, the shell filter layer portion 30 is formed by filling the shell by using the shell as a dephosphor by introducing the treated water into the inlet port 21 to the outside of the main body 10. After passing through 30, the dephosphorization part 20 for flowing into the inlet part 11 of the main body 10 after the removal of the phosphorus (P) remaining in the treated water while flowing through the outlet 22 is integrated. It is formed as.

In this case, the inlet port 21 of the dephosphorization part 20 is formed at the lower side and the outlet port 22 is formed at the upper side so that the treated water passes through the shell medial layer part 30 of the dephosphorization part 20 from the lower side to the upper side. The flow of the treated water passing through the layer part 30 becomes an upflow type, so that the sludge and dephosphorization efficiency included in the treated water can be increased, and the lower end of the dephosphorized part 20 is included in the treated water. A portion of the sludge that has been settled down is formed in the hopper 23 for removing and the hopper 23 is equipped with an opening and closing device 23a for taking out the sludge.

In addition, the shell filter layer portion 30 is composed of a filter box 31 for receiving the shell 40 is formed to form a filter layer and the filter box frame 32 for receiving the filter box 31, the In the filter box frame 32, a lifting means 32a for lifting the lifting upper portion of the dephosphorization part 20 by using a hoist is formed.

In addition, the filter box frame 32 has a partition partition 32b for storing the filter box 31 stacked in multiple stages at a spaced interval up and down to form a multi-layer shell media layer to form a shell of multiple stages. It is possible to increase the removal efficiency of dephosphorization through the media layer.

In addition, by forming a handle 31a on the front of the filter box 31 so that the shell filter layer portion 30 has a drawer-type opening and closing structure to facilitate the use, the upper side is convenient for transportation using a hoist A lifting means 31b is formed to form a wheel, and a wheel 31c is formed on the lower side thereof, and the opening and closing by a lid is possible.

On the other hand, the partition box 32b of the filter box 31 and the filter box frame 32 is of course made of a network structure for the flow of water.

In addition, the main body 10 is formed inside the main body 10 by forming a treated water inflow induction line 15 for attracting the dewatered treated water connected to the inlet 11 to the lower side of the main body 10 to be introduced therein. In order to improve the responsiveness according to the increase of residence time, it is possible to obtain better treatment efficiency.

In addition, using the zeolite 50 as an ion exchanger on the upper side of the dephosphorization part 20, a zeolite media layer layer 60 for removing even nitrogen (N) remaining in the treated water even after the highly advanced biological treatment is once again removed. By further forming, the water quality of the effluent can be made more stable.

In this case, the zeolite filter layer part 60 may be formed in a separate structure from the shell filter layer part 30, but the filter medium accommodated in the upper portion of the filter box frame 32 constituting the shell filter layer part 30. The zeolite 50 may be stored in the box 31 so as to be formed in the same manner as the shell media layer 30.

On the other hand, the main body 10 of the final settling tank of the present invention may be provided with a stirring facility 17 that is rotated by the operation of the motor 16, which is a known component that can be provided in a conventional settling tank .

Therefore, the final sedimentation tank of the present invention configured as described above requires a separate system for removing phosphorus by removing the phosphorus, which has not been largely removed through the biological advanced treatment process, by crystallization dephosphorization through the dephosphorization unit 20. Of course, there is no additional amount of sludge generated when removing phosphorus by removal by crystallization.

At this time, the principle of phosphorus removal using the shell is as follows.

1) Main ingredient of shell: CaCO ₃

2) the number of phosphorus in the _{reaction: CaCO 3 + H 2 O →} Ca 2 + + HCO 3 - + OH -

3) reaction of the city water: ^{2 +} 5Ca 3HPO + ₄ ^{2 -} → 4OH + Ca10 (OH) ₂ (PO ₄₎ 3 + ₆ H ₂ O

                                  Hydroxyapatite (crystallization) → phosphorus removal

In addition, the shell filter layer 30 formed on the dephosphorization part 20 is an environmentally friendly process as a shell layer for dephosphorizing the shell, but is discarded as marine waste without using expensive dephosphor agents currently used in the crystallization method. By using the shell that is losing, there is an advantage to recycle the waste.

In addition, by forming the zeolite layer 60 formed on the dephosphorization part 20, even a small amount of nitrogen components remaining after the advanced biological treatment may be further removed.

On the other hand, the removal of nitrogen using the zeolite is a known technique will be omitted the description of the principle.

In addition, due to the lifting means (32a, 31b) formed in the filter box frame 32 and the filter box 31, the shell layer layer 30 is the de-portion part using a convenient transportation means using a hoist after several times 20 can be easily and conveniently transferred to the regeneration tank to be regenerated and then mounted on the dephosphorization unit 20 as it is, so that the regeneration use of the shell media layer part can be easily performed.

To this end, the final settling tank of the present invention is further provided with a conveying means (1), such as a hoist, closed shell regeneration tank (2), zeolite regeneration tank (3), through the outlet portion 13 of the main body 10 Recirculation pump 6 for conveying a part of the discharged water to the inlet 21 of the dephosphorization part 20 in the discharge tank 4 for storing the discharged water discharged and the previous stage of the discharge tank 4 to circulate. By further providing a recycling tank (5) formed is to be able to obtain a more excellent phosphorus removal efficiency.

This can be confirmed through the following experimental data.

In addition, the shell to be filled in the shell filter layer 30 is a phosphorus removal rate is higher the smaller the size of the particles, but the filling of 4mm ~ 2mm in consideration of the management and the life.

Phosphorus removal efficiency can be confirmed through the following experimental values.

       1 is a schematic configuration diagram of the present invention.

       Figure 2 is a block diagram of the closed angle filter layer mounted on the present invention.

       Figure 3 is a main part of the state to transfer the shell material layer portion from the dephosphorization portion of the present invention using the transfer means.

      4 is a flow chart of the treated water according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1: transfer means 2: shell regeneration tank

3: zeolite regeneration tank 4: discharge tank

5: recirculation tank 10: main body

11; Inlet 12: Sludge Outlet

13: outlet 14: hopper

15: treatment water inflow line 20: dephosphorization

21: inlet 22: outlet

23: hopper portion 30: shell shell layer portion

31: Media box 32: Media frame

40: shell 50: zeolite

60: zeolite filter layer part

Claims (9)

delete delete delete delete Treated water treated through the advanced biological treatment of wastewater and sewage is introduced through the inlet 11 of the main body 10, and the sludge remaining in the treated water is precipitated to the lower part of the main body 10 so that the sludge outlet 12 In the known final sedimentation tank 21 configured to be discharged through the) and to be discharged through the outlet portion 13 formed on the upper side of the main body 10, The shell filter material layer part 30 which fills the treated water into the inlet 21 to the outside of the main body 10 and fills the shell with dephosphorization material is formed. Dephosphorization part for flowing into the inlet 11 of the main body 10 after removal of the phosphorus (P) remaining in the treated water while flowing through the outlet 22 after passing through the shell filter layer portion 30 20 is integrally formed, The inlet port 21 of the dephosphorization part 20 is formed on the lower side and the outlet port 22 is formed on the upper side so that the flow of the treated water passing through the shell media layer 22 is made upflow. The lower end of the dephosphorization part 20 is integrally formed with a dephosphorization part 20 in which a hopper part 23 equipped with an opening / closing device 23a for withdrawing sedimented sludge is formed. On the outside of the main body 10, a conveying means 1 for conveying the shell media layer part 30 and a dephosphorization part provided with a closed shell regeneration tank 2 are integrally formed. The shell media layer 30 is a shell box 31 having a mesh structure so that the shell 40 is accommodated to form the media layer The filter box frame 32 is configured to accommodate the filter box 31, and the filter box frame 32 is integrally formed with a dephosphorization unit having a lifting means. The filter box frame 32 has a departing portion formed with a partition partition 32b having a network structure for storing the filter box 31 stacked in multiple stages at intervals of up and down spaced apart to form a multi-layer shell layer. The final settling tank formed integrally. The final sedimentation tank according to claim 5, wherein the filter box (31) has a handle (31a) to form a dephosphorization part integrally formed to have a drawer open / close structure. delete delete delete

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