KR20130131613A - Device to cohere and to dispose of wastes water - Google Patents

Abstract

The present invention relates to a waste water cohering treatment apparatus realizing a compact apparatus by forming each treatment tub in one apparatus; purifying the waste water sby successively; discharging foreign substance automatically by coagulants; removing odor at the beginning of the mixing in the first mixing tub; and improving waste water purification efficiency by disposing microsludge comtained in the third processing water by lowering the odor and pollution load.

Description

[0001] The present invention relates to a device for coagulating wastewater,

The present invention relates to a wastewater flocculation treatment apparatus, and more particularly, to a wastewater flocculation treatment apparatus capable of automatically discharging foreign matter contained in wastewater through a flocculant and automatically discharging wastewater, In addition to eliminating the odor from the wastewater in the early stage, it is processed to the 2nd and 3rd stage, and the odor and the pollutant load to the raw water of the wastewater are remarkably lowered, and the fine flocs contained in the 3rd wastewater are sludge processed, And each treatment tank is continuously formed in one apparatus so that a compact apparatus can be realized.

As well known, wastewater such as leachate, sewage, sewage and manure from industrial sites, livestock farms, and households contains not only large amounts of residues but also biological oxygen demand, chemical oxygen demand, suspended solids content, etc. If the landfill or water purification treatment is carried out because the treatment method is not satisfied, the destruction of the natural environment is seriously proceeded due to the soil pollution around the wastewater treatment plant and the contamination of the river water.

Accordingly, after the wastewater is separated and separated from the wastes such as sand and dirt, the wastewater is purified by the wastewater purification system and discharged to a river or the like to reduce environmental pollution.

In other words, conventionally, manure from portable toilet and manure generated from various housing facilities are treated with chemicals or microorganisms and recycled as compost. However, since it uses a large amount of chemical chemicals and the discharge standard is high, It is disadvantageous in that it is expensive and time consuming due to the processing.

Also, it is necessary to maintain the proper temperature of waste generated in various food companies, beverage companies, group food service, large restaurants, highway resting places, etc., and to use them as compost or feed There is a way. It is a fact that the method to utilize as compost is not accepted at the farmhouse because of salt remaining in food waste or food processing waste. In addition, since a large amount of the garbage is generated, a large drying apparatus is required for the purpose of treating the food waste. Or a method of directly incinerating food waste using an incinerator is also used, but it is sometimes used in a case where the amount of food waste generated is small. This method is not popularized because of the disadvantage that the cost of drying or incineration of food waste is high.

To reduce the cost of treating food waste, food waste can be compressed to lower the solids content and thus save on drying costs for solids. The food wastewater generated at this time has a method of evaporating oil or other fuel as an energy source. However, nowadays, it is preferred to use low-cost marine dumping.

Let's look at the case of an livestock farmer. Although the livestock wastewater generated in the enterprise type livestock farming farm or the general livestock farming farm is treated by the microbiological method, there is no solution for the odor. In addition, the amount of livestock wastewater generated is daily from 5.2kg to 6.7kg per poultry. In the manure, the pigs are sifted, mixed with sawdust, fermented and used as organic fertilizer. Pig urine is mixed with a part of pig shit and sent to the insoluble tank, and is used as an organic liquid fertilizer due to natural evaporation and enzymatic action. Due to the stench generated at this time, there is a lot of problems in the development of the land around the livestock farms.

Another method is to maintain a constant temperature in an enclosed space and produce a biogas or methane gas for various purposes although the generation period varies depending on the season. However, there is a problem in that the initial installation cost is high and the space is very heavy There are disadvantages. In this method, methane gas is produced and the remaining waste and wastewater are insufficiently decomposed to be used as a liquid fertilizer, requiring a second composting time.

In general wastewater treatment methods, it is common to treat various wastewater by various methods such as activated sludge method and catalytic oxidation method, and final treatment by using sand or other filtration media.

The activated sludge process separates residues such as soil, sand, and debris mixed in the wastewater from the gypsum and then continuously separates the wastewater into wastewater by separating the residues in one reactor. In this way, microorganisms are grown to utilize the heavy metals and organic matter remaining in the wastewater as the basic growth sources of microorganisms. Thus, the saturated microorganisms continue to ingest heavy metals and organic matter, and the necrotized microorganisms become sludge, precipitating or floating. Finally, the sludge is submerged and the water located in the upper part, that is, the supernatant, is discharged. Such an activated sludge method can not cope with fluctuations in the amount of incoming wastewater flowing in a large amount, can release untreated sludge at a high concentration when an abnormal phenomenon or an accident occurs with microorganisms, requires a large maintenance cost, It takes a lot of processing time.

In the contact oxidation method, contact materials are filled in a contact vessel to form a filtrate, and enough dissolved oxygen is supplied by stirring of the aeration tank to purify the biofilm attached to the contact material by repeated contact with the wastewater. It is difficult to remove the excess sludge periodically, and there is a disadvantage that the sludge of high concentration can be discharged without fail when an abnormal phenomenon or an accident occurs.

In view of this, a wastewater flocculation treatment apparatus has been disclosed in which a flocculant is added to a stirring tank containing wastewater and then agitated to coagulate organic matters and inorganic substances contained in wastewater. In the conventional wastewater flocculation treatment apparatus, a stirring tank and a settling tank are subdivided In addition, there is a limitation in the process of sludge agglomeration of foreign matters. Further, since the respective treatment tanks such as the stirring tank and the settling tank are separated from each other, the continuous treatment of the wastewater is impossible, There is a problem that it occupies a lot of installation space.

The present invention has been proposed in view of this point, and it is an object of the present invention to provide a method and an apparatus for collecting foreign matter contained in wastewater through a coagulant and automatically discharging the wastewater through a screen tank, In addition to eliminating the odor generated in the wastewater at the initial stage of agitation, the odor and pollutant load on the raw water of the wastewater are significantly lowered while the second and third wastewater are treated, and the fine flocs contained in the third wastewater are sludge processed, And to provide a wastewater flocculation apparatus capable of improving the purification efficiency and continuously forming each treatment tank in one apparatus to realize a compact apparatus.

The present invention for solving this problem, when the wastewater is supplied to separate the solids and liquids remaining in the wastewater and the solids are discharged to the outside, when the flocculant is put in the state containing only the liquid material is received through the stirring blades Mixing tank for stirring; A final treated water receiving tank containing the final treated water relatively cleaned as compared with the wastewater; A replenishment tank containing groundwater or clean water; When the waste water, the final treated water, and the supplemental water flows from the mixing tank, the final treated water receiving tank, and the supplemental water receiving tank, the stirring water is agitated through a stirring blade to form a floc through condensation of foreign matters, thereby generating sludge. Agitated portion made; A sedimentation unit having a plurality of sedimentation vessels continuously receiving the water introduced from the agitation unit to sediment the sludge contained therein and overflowing only the water on the upper side to the next stage; Separating the solid matter from the liquid matter in the wastewater flowing into the mixing tank, separating the sludge in the treated water flowing from each of the stirring vessels of the stirring section into the stirring vessel of the next step from the treated water, A screen portion comprising a plurality of screen tanks installed between respective portions for separating the sludge in the water from the treated water; And pumped water from the last sedimentation tank of the sedimentation unit to remove fine suspended substances and heavy metals contained in the treated water in the course of passing through the multistage filter, and the final treated water is discharged or pumped into the treated water receiving tank. It includes a filter unit for reuse.

Preferably, the mixing tank is provided with a coagulant feeder capable of injecting a coagulant in a predetermined amount on one side thereof, a driving motor is fixed to an upper central portion thereof, and stirring wings are mounted on upper and lower portions of the driving motor, Wherein the waste water is preliminarily treated through agitation of wastewater, treated water, makeup water and flocculant before the agitating operation, and the lower face is inclined toward one side or the central direction, and a discharge pipe having a valve is connected to the lowermost position of the inclined part ; The final treated water receiving tank and the makeup water receiving tank are each configured such that the lower surface is inclined toward one side or the central direction, and discharge pipes having valves are connected to the lowermost position of the inclined side.

Preferably, the stirring unit, when the final treated water and the supplemental water flows into the wastewater pre-treated from the mixing tank, the final treated water receiving tank and the supplemental water receiving tank, respectively, by stirring them to form a floc through foreign matter aggregation Primary stirring tank to produce; Sludge is filtered out of the primary treated water discharged from the primary stirring tank in a state in which the volume is 2 to 2.5 times larger than the primary stirring tank, and discharged to the outside, and only the primary treated water is discharged. A secondary agitation tank which introduces a flocculant, a final treated water, and supplemental water, and further forms a floc through flocculation of foreign substances to generate sludge; And a volume of 2 to 2.5 times larger than that of the first stirring tank so that sludge is filtered out of the secondary treated water discharged from the second stirring tank and discharged to the outside, and only flocculant is added and stirred to form a floc through foreign matter aggregation. It may include a third stirring tank to produce sludge.

Preferably, the primary stirring tank is composed of two primary stirring tank A, the first stirring tank B, the mixing tank, the final treated water at the time point of 60 ~ 80% of the stirring process in the first stirring tank A Waste water, final treatment water, supplemental water from the receiving tank, the supplemental water receiving tank may be configured to be introduced and stirred into the primary stirring tank B.

Preferably, a coagulant feeder for supplying a quantitative amount of a coagulant may be installed at each of the mixing tank, the secondary agitating tank, and the third agitating tank.

Preferably, in the case of a large-scale processing facility, each of the stirring vessels is provided with a plurality of driving motors having a central portion and an equilateral angle around the central portion, and stirring vanes are mounted on the axes of the respective driving motors, And the wastewater and treatment water in the respective agitating vessels are agitated with the flocculating agent in accordance with the driving, and each of the agitating blades is mounted in a direction to guide the water stream downward, May be configured to rotate in a direction opposite to the stirring wing of the other portion while being mounted in the opposite direction.

Preferably, the shape of each of the stirring tank is made of a rectangle, the mixing direction of the waste water, the final treated water, the replenishing water rotates in accordance with the rotation of the stirring blade inside the respective stirring tank so that the vortex can be generated Protrusions may be formed.

Preferably, the settling portion is provided so that a process water inflow frame passing through the upper and lower portions is spaced apart from the lower surface of the outer wall of each of the settling tanks by a predetermined distance, and the settling portion of the settling portion, And the water overflowing from the agitating unit or the settling tank in the previous stage is introduced into the respective treatment water inflow molds, and only the upper side water of the inflowing water is supplied to the outer wall of each of the settling basins, The lower surface of each of the sedimentation tanks is inclined toward the central part or one side so as to collect the sludge and a sludge discharge pipe is connected to the lower part of the inclined part so as to discharge the sludge downward .

Preferably, each of the settling basins is formed so that the volume gradually increases toward the rear with reference to the moving direction of the treated water.

Preferably, each of the process water inflow dies is provided with a wire net at the inlet port.

Preferably, the screen unit includes a first screen tank installed at an upper portion of the mixing tank to separate solids from wastewater flowing into the mixing tank from a liquid material; A second screen tank provided between the primary agitation tank and the secondary agitation tank so as to be inclined to separate sludge contained in the primary treatment water from the primary treatment water; A third screen tank installed at an angle between the secondary agitator and the tertiary agitator to separate the sludge contained in the secondary water from the secondary water; And a fourth screen set sloped between the third stirring tank and the settling unit to separate the sludge contained in the third treated water from the third treated water.

Preferably, each of the screen groups has a screen conveyor connected to the screen between a driving roller and a driven roller, and the driving roller is connected to the driving motor so as to transmit power so that the screen conveyor is driven by the driving motor, The waste water or each treated water is configured to pass downward while transferring the solid matter or sludge to the outside while continuously rotating between the drive roller and the driven roller; The screen conveyor of the second screen group to the fourth screen group is inclined in one direction so as to collect the respective treated water. At the lowermost part of the inclined part, a conveyance pipe for conveying the collected treated water to the next stage is connected ; A vibrator is installed on one side of each of the screen tanks so as to smoothly separate the sludge from the treated water; A guide plate is installed at a screen conveyor discharge end of the second to fourth screen sets to separate sludge filtered by the screen conveyor from the screen conveyor; Each of the screen tanks is provided at its upper side with wash water nozzles each capable of rotating 360 ° in order to remove sludge from the screen conveyor, and the wash water nozzle may be connected to the final treated water inflow pipe or the makeup water inflow pipe.

Preferably, the secondary stirring tank and the tertiary stirring tank are arranged in parallel, the lower surface of the secondary stirring tank is provided with the third screen tank, and the lower surface is inclined in one direction so as to collect the secondary treated water to one side A second treatment water storage tank is provided below the third screen tank and an underwater pump is disposed at the lowermost portion of the inclined portion of the secondary treatment water storage tank so that the secondary treatment water can be introduced into the tertiary stirring tank .

Preferably, the mixing tank, the final treatment water receiving tank, the supplemental water receiving tank, the respective stirring tank, the upper portion of the secondary treatment water storage tank is not discharged together with the treated water, the mixing tank, the final treatment water 360 ° rotatable wash water nozzles are respectively installed to clean foreign substances trapped in corners of the holding tank, the supplemental water holding tank, the respective stirring tanks, and the secondary treated water storage tank through water spraying, and the washing water nozzles It may be made in connection with the treated water inlet pipe or supplemental water inlet pipe.

In the present invention, a flocculant is added together with various kinds of wastewater, makeup water or final treated water, and stirred through a multistage agitating unit, whereby inorganic matter and organic matter remaining in the wastewater are stirred to form flocs, Continuous agitation will enable the coarsening of the flocs. At this time, the generated sludge is smoothly discharged to the outside without being destroyed, and the treated water can be filtered and guided to the next process.

In addition, since the stirring tank and the screen tank are formed in a multi-stage structure, the flocs are formed gradually smaller in each step, and the fine flocs can be sludgeized and removed, and the sedimentation units are also multi-stage, so that fine flocs and sludge can be precipitated and removed .

In addition, in the settling tank, the inlet height of each settling tank is gradually lowered from the inflow position of the third treated water to the discharge position, so that the treated water flows naturally without any additional pump and flows into the next step, A mixing tank, a replenishment water receiving tank, a final treated water receiving tank, a stirring portion, a sedimentation portion, a screen portion, and a filter portion are sequentially connected to realize a compact device.

1 is a perspective view of a wastewater coagulation apparatus according to the present invention;
2 is an exploded view showing a wastewater treatment sequence of a wastewater coagulation apparatus according to the present invention.
3 is a detailed view of a primary stirring apparatus of a wastewater coagulation apparatus according to the present invention.
4 is a detailed view of a second agitating device and a second treated water storage tank of the wastewater coagulation apparatus according to the present invention.
5 is a detailed view of a third stirring device and a settling tank of a wastewater coagulation apparatus according to the present invention.
6 is a plan view of a stirring tank of a wastewater coagulation apparatus according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Wastewater flocculation treatment apparatus according to the present invention, as shown in the wastewater, the final treated water, supplemental water inflow and input the flocculant and stirred, to form a floc through flocculation performance of the flocculant, discharge the sludge, only the treated water In order to do this, the treated water can be discharged or reused to the next stage to be discharged or reused. To this end, wastewater is introduced and stored temporarily, while the final treated water and groundwater or clean water are introduced, a flocculant is added, and agitated. Mixing tank 10 for pretreatment; A final treatment water receiving tank 20 for temporarily storing final treatment water relatively clean compared to wastewater; A replenishment water receiving tank 90 for storing ground water or clean water; Stirring unit consisting of a plurality of agitator tank 30, 40, 50 to form a floc while stirring the waste water, the final treated water, supplemental water inlet; A sedimentation unit comprising a plurality of sedimentation tanks (60) for sedimenting the fine sludge contained in the treated water; A screen portion composed of a plurality of screen tanks 12, 42, 61, and 81 for separating the sludge generated from each stage and each treatment water; And a filter unit 70 for filtering the fine sludge contained in the treated water without being precipitated in each settling tank 60 of the settling unit.

The mixing tank 10 is formed in a box shape so as to contain wastewater, and its lower surface is inclined at one side or in a central direction. A discharge pipe 19 having a valve is connected to the lowermost position of the inclined part, (Not shown) so as to be capable of first waterproofing and is provided with a flocculant supply device 11 capable of injecting a flocculant in a fixed amount and a first screen assembly The solid material contained in the raw water is separated from the wastewater and discharged to the outside when the raw water is introduced. A driving motor 13 is fixed to the mixing tank 10 and a stirring blade 14 is attached to the upper and lower portions of the shaft of the driving motor 13 to apply wastewater, final treated water, makeup water and flocculant, And pre-processing is performed before the full stirring operation through the stirring tank 30 (40) 50 described later.

The final treated water receiving tank 20 may be formed in a box shape so as to contain treated water similarly to the mixing tank 10 and the replenishment water receiving tank 90 may be formed in a hollow shape . The bottoms of the final treated water receiving tank 20 and the makeup water receiving tank 90 are inclined at one side or in a central direction and discharge pipes 29 and 99 having valves at the lowest positions of the inclined portions are connected do. In the final treatment water receiving tank 20, since the final treated water does not flow at the initial stage of driving, clear water is used for the final treatment water receiving tank 20.

Each of the stirring tanks 30, 40 and 50 constituting the stirring part includes wastewater containing a flocculant pretreated from the mixing tank 10, final treated water from the final treated water receiving tank 20, and a supplemental water containing tank ( 90) when the replenishment water is introduced, the sludge in the primary agitating tank 30 and the primary treated water discharged from the primary agitating tank 30 are agitated by forming a floc through foreign matter agglomeration of the flocculant. Secondary agitator (40) and secondary agitation to form sludge by forming a floc through agglomeration of foreign substances by filtration and discharged to the outside and only the first treated water is introduced, and a flocculant, final treated water and supplemental water are added and stirred. Sludge is filtered out of the secondary treatment water discharged from the tank 40 and discharged to the outside, only the secondary treatment water is introduced, and a small amount of flocculant is added and stirred to form a floc through flocculation of fine foreign substances to generate sludge. It consists of the tertiary stirring tank 50 The primary stirring vessel 30 is at the top, and the secondary stirring vessel 40 and the tertiary stirring vessel 50 are configured below.

The primary stirring tank 30 is formed in a box shape to hold the waste water, the final treated water, and the replenishment water, and the waste water supply pipe 15, the final treated water inlet pipe 21, and the replenishment water inlet pipe 91 at the top. ) And a plurality of or single drive motor 33 is installed downward, and the stirring blade 34 for stirring the flocculant, the waste water, the final treated water, and the replenishment water is installed on the shaft of the drive motor 33. , The lower surface is formed to be inclined toward the center or one side to collect the sludge, the V-shaped discharge pipe 35 is connected to the lower portion of the inclined portion to discharge the sludge downward.

In addition, the primary stirring tank 30 is composed of two primary stirring tank A (31), primary stirring tank B (32) two to 60-80% of the stirring process in the primary stirring tank A (31) At this time, the wastewater, the final treated water, and the supplemental water from the mixing tank 10, the final treated water receiving tank 20, and the supplemental water containing tank 90 are introduced into and stirred into the primary stirring tank B32.

The secondary stirring tank 40 is formed in the same shape as the primary stirring tank 30, the upper portion of the primary stirring tank A (31) or primary stirring tank B (32) forming the primary stirring tank (30) ), The second screen tank 42 made of mesh is installed to be inclined to filter out the sludge from the outside and flow out only to the first treatment water, and the final treatment water inlet pipe to replenish the final treatment water and clean replenishment water. 21 and the replenishment water inlet tube 91 are positioned, and a flocculant feeder 41 that is waterproof is provided while supplying a fixed amount of flocculant, and a plurality of or single drive motors 43 are installed downwards, and are driven. The stirring blade 44 for stirring the flocculant, the wastewater, the final treated water, and the replenishment water is installed on the shaft of the motor 43, and the lower surface thereof is inclined toward the center or one side to collect the sludge, At the bottom, ship the sludge downward Be V-shaped discharge pipe 45 of the to be made are connected. Such a second agitating tank 40 is configured to be 2 to 2.5 times as large as the capacity of the first agitating tank 30 in consideration of the final treated water to be replenished and the capacity of the replenishing water.

A third screen tank (81) is provided at an upper portion of the second agitating tank (40) and is inclined. The lower surface of the second screen water tank (80) is inclined in one direction so as to collect the second treated water to one side. A submerged pump 82 is disposed at the lowermost portion of the inclined portion of the secondary treatment water storage tank 80 and the secondary treatment water is supplied to the tertiary stirring tank 50 And is configured to be pumped. The third agitating tank 50 may have a volume equivalent to that of the second agitating tank 40.

The third stirring tank 50 is also provided with a coagulant feeder 51 for supplying a coagulant in a predetermined amount to the upper portion thereof and a plurality of or a single driving motor 53 And a stirring blade 54 for stirring the flocculant and the secondary treatment water is provided on the shaft of the driving motor 53. The lower surface of the stirring blade 54 is inclined toward the center or one side so as to collect the sludge, And a V-shaped discharge pipe 55 is connected to the lowermost part of the inclined part so as to discharge the sludge downward.

In the third stirring tank 50, no separate treatment water is replenished, but in some cases, a final treated water inflow pipe (not shown) or a replenishment water inflow pipe (not shown) is positioned to replenish the final treated water or replenishment water It is possible.

In the case of a large-scale processing facility, the stirring tanks 30, 40 and 50 are provided with a plurality of driving motors 33, 43 and 53. The driving motors 33, 43 and 53 Are disposed at the central portion of each of the stirring tanks 30, 40 and 50 and equidistantly around the central portion of the stirring tanks 30 and 40 and the stirring vanes 34 and 44 ) 54 are respectively installed and the waste water and treated water in each of the stirring tanks 30, 40 and 50 are agitated with the flocculant in accordance with the driving of the driving motors 33, 43 and 53 A plurality of stirring vanes 34, 44 and 54 are installed to guide the water stream in a downward direction and the stirring vanes 34, 44 and 54 at the center are mounted on the stirring vanes 34, 44 and 54 while rotating in opposite directions to the stirring vanes 34, 44 and 54 of the other parts so that the water streams are rotated in one direction without colliding with each other, In case of processing, one drive motor Respectively.

In addition, the shape of each stirring vessel 30, 40, 50 is made of a rectangular shape, the inside of each stirring vessel 30, 40, 50 to the rotation of the stirring blades 34, 44, 54 Protrusions 36, 46, 56 are formed to change the direction of the rotating waste water, the final treated water, and the replenishment water.

In addition, the upper part of the mixing tank 10, the treated water receiving tank 20, the supplemental water receiving tank 90, each stirring tank 30, 40, 50, the supplemental water inlet pipe 91 or the final treated water A wash water nozzle (17) (27) (37) (47) (57) (97) rotatable 360 ° to communicate with the inlet (21) is provided for the mixing tank (10), the treatment water receiving tank (20), and supplementation. By allowing water to be sprayed in various directions on the water tank 90 and each of the stirring tanks 30, 40 and 50, the agitation is finished and the discharge of each treated water through each of the discharge pipes 35, 45 and 55. After this is completed, it is preferable to remove the secondary treatment residues remaining therethrough so that they can be introduced into the next step.

A fourth screen tank (61), which is a mesh screen, is installed at an upper portion of the discharge portion of the third stirring tank (50) to drain the sludge to the outside, and a plurality of sedimentation tanks (60)

At this time, each of the screen groups 12, 42, 61, and 81 constituting the screen portion is constituted such that a screen conveyor 73 made of mesh is connected between the driving roller 74 and the driven roller 75, 74 are connected to a drive motor (not shown) so as to transmit power so that the screen conveyor 73 continuously rotates between the drive roller 74 and the driven roller 75 in accordance with the driving of the drive motor to drive the solids or sludge The wastewater or each treatment water is configured to pass downward while being transferred to the outside and the treated water is supplied to the lower portion of the screen conveyor 73 of the second to fourth screen groups 42 to 61 And a transfer pipe (76) for transferring the collected treated water to the next step is connected to the lowermost part of the inclined part.

A vibrator 77 is installed on one side of each of the screen tanks 12, 42, 61 and 81 so as to smoothly separate the sludge from the treated water and a second screen trough 42 A guide plate 78 or a brush (not shown) made of rubber or synthetic resin is attached to the discharge end of the screen conveyor 73 of the screen conveyor 73 for separating the sludge filtered by the screen conveyor 73 from the screen conveyor 73 And wash water nozzles 79 capable of rotating by 360 ° are installed at one side of the top of each of the screen tanks 12, 42, 61, and 81 so as to remove sludge from the screen conveyor 73 have. Of course, it is obvious that each wash water nozzle 79 should be configured to communicate with the makeup water inlet pipe 91 or the final treated water inlet pipe 21.

The washing water nozzle 87 is connected to the supplementary water inlet pipe 91 or the final treated water inlet pipe 21 so as to be rotatable by 360 degrees on the upper side of the upper side of the secondary treated water storage tank 80, And finally cleaned up after finishing.

Each of the sedimentation tanks 60 constituting the sedimentation section is formed in a box shape and is provided so as to be spaced from the bottom wall of the outer wall of the sedimentation tank 60 by a predetermined distance, An inlet 63 is formed in the treatment water inflow frame 62 in the sedimentation tank 60 of the treatment water inflow frame 62 so that the overflowed water from the agitation unit or the settling tank 60 in the previous stage flows into the treatment water inflow frame 62 An inlet port 63 is connected to the outer wall of each settling tank 60 so that only the upper side of the inflowed water can overflow to the next stage and the lower surface of each settling tank 60 is connected to one side And a sludge discharge pipe 65 is connected to the lowermost portion of the inclined portion so as to discharge the sludge downward.

It is preferable that each settling tank 60 is formed such that the volume gradually increases toward the rear with respect to the moving direction of the tertiary treatment water so as to increase the sedimentation efficiency of the sludge by lowering the flow rate of the tertiary treatment water, At the position of the inlet 63 of the treatment water inlet mold 62, a filter net 66 is formed so as to filter the fine sludge components contained in the tertiary treatment water, It is preferable that the mesh size is gradually reduced toward the back with respect to the direction of the sludge.

The filter unit 70 includes a plurality of filters to filter the pumped tertiary treatment water from the final settling tank 60 of the settling tank 60. The fresh water capacity of the filter unit 70 is adjusted by the final settling tank 60 So that the flow of the treated water in each step is not delayed when the tertiary treated water is filtered.

In addition, the final treated water through which the fine sludge component has been removed while passing through the filter unit 70 is discharged or pumped to the final treated water receiving tank 20 so as to be reused.

Reference numerals 16, 22, 67 and 94 denote submerged pumps, 92 denotes a fifth screen tank for discharging the sludge filtered through the first screen tank 12 and the second screen tank 42 Reference numeral 93 denotes a sixth screen tank for discharging the sludge discharged through the third screen tank 81, the fourth screen tank 61 and the fifth screen tank 92 to the outside.

When the wastewater flows into the wastewater supply pipe 15 according to the present invention, the wastewater is discharged to the outside through the first screen tank 12 to remove the solids contained in the wastewater, Passes through the first screen tank (12) and is received in the mixing tank (10).

In this state, the coagulant is supplied through the coagulant feeder 11, the final treated water or the supplemental water is introduced from the final treated water receiving tank 20 or the supplemental water receiving tank 90, and then the driving motor 13 is driven. The wastewater, final treated water, make-up water and flocculant are stirred and pretreated. The preprocessing time is about 30 seconds. Depending on the nature of the wastewater, only the coagulant may be added without the final treated water or make-up water and stirred with the wastewater itself.

When the pretreated wastewater of the mixing tank 10, the final treated water of the final treatment water receiving tank 20, and the replenishment water of the supplemental water receiving tank 90 are pumped to the primary stirring tank 30, the primary stirring tank ( The drive motor 33 of 30) is driven to agitate the wastewater containing the pretreated flocculant, the final treated water and the supplemental water to form a floc through agglomeration of foreign substances to generate sludge. The final treated water, makeup water, and wastewater may be mixed with water at a ratio of 1: 1: 1 on a weight basis. However, wastewater with a low pollutant load can be treated with only wastewater without final treatment and replenishment.

The reason why the wastewater is agitated with the flocculant in the mixing tank 10 is that the position of the primary agitator 30 is located at the highest position in the entire apparatus and it is difficult to replenish the flocculant from time to time. It is advantageous to form a flock through the flocculant.

At the initial stage of driving the drive motor 33, the stirrer vane 34 is rotated at a high speed to increase the reaction speed of the flocculant, thereby enabling coarse flicking in a short period of time. Thereafter, the stirring vane 34 is rotated at low speed So that the sludge can be precipitated in a downward direction without being broken, thereby driving the pattern for improving the sedimentation efficiency.

In addition, the primary stirring tank 30 is equipped with two primary stirring tank A (31) and the primary stirring tank B (32), the stirring process in the primary stirring tank A (31) is 60 ~ 80% When the stirring blade 34 is rotated at a low speed, the mixing tank 10, the treated water receiving tank 20, and the supplemental water receiving tank discharge the waste water, the final treated water, and the supplemental water from the first stirring tank B. Repeating the stirring process by introducing into (32), the first stirring process is duplicated in two primary stirring tank A (31) and the first stirring tank B (32) for a predetermined time and the first stirring time as much as the corresponding You can save 20-40%.

The primary treated water stirred through the primary agitation tank A, B (31) (32) is discharged downward through the discharge pipe (35), and the primary stirred tank A, B (31) A second screen tank 42 is provided between the stirring tank 40 so that the sludge contained in the primary treated water discharged from the primary agitation tank 30 is filtered by the second screen tank 42, And only the primary treated water flows into the secondary agitation tank 40.

If the primary treated water is contained in the secondary agitating tank 40, the ratio of final treated water, makeup water and primary treated water is 0.5: 0.5: 1 from the final treated water receiving tank 20 and the replenishing water receiving tank, A singer is necessary so that it can be contained in the tea agitator 40. This is the amount of water required for the purification of food wastewater or livestock wastewater, which has a high pollutant load. The wastewater having a low pollutant load does not need the water in the mixing tank 10 or the secondary stirring tank 40, but only the amount of the flocculant is added to the wastewater and stirred.

Then, the coagulant is injected through the coagulant feeder 41, and the driving motors 43 are driven and agitated to coagulate the foreign substances to form the flocs. At this time, the ratio of the water can be adjusted according to the characteristics of the primary treatment water.

Since the volume of the secondary agitation tank 40 is 2 to 2.5 times larger than that of the primary agitation tank A 31 or the primary agitation tank B 32, the water is supplied through the final treated water and the replenishing water The first treated water, the final treated water and the replenishing water can be sufficiently accommodated, and the agitation pattern of the secondary agitation tank 40 can be performed in the same manner as the primary agitation tank 30.

The second treated water that has been stirred through the second stirring tank 40 is discharged downward through the discharge pipe 45. A third screen tank 81 is provided below the second stirring tank 40, The sludge contained in the treated water discharged from the tea agitator 40 is filtered by the third screen tank 81 and discharged to the outside so that only the secondary treated water is contained in the secondary treated water storage tank 80.

At this time, if an ozone generator is provided at the inlet of the secondary treatment water in the secondary treatment water storage tank 80, it is possible to sterilize the secondary treatment water with ozone and, at the same time, destroy the untreated organic matter, It is possible to increase the efficiency of the tertiary stirring.

The lower surface of the secondary treated water storage tank 80 is inclined in one direction so as to collect the secondary treated water to one side and the submerged pump 82 is located at the lowest inclined portion. The secondary treatment water is pumped by the submersible pump 82 in the secondary treatment water storage tank 80, so that there is an advantage that no residual secondary treatment water remains.

The secondary treated water collected in the secondary treated water storage tank 80 flows into the tertiary stirring tank 50 through the pumping of the submerged pump 82. After the flocculant is supplied through the flocculant supply unit 51 By driving each driving motor 53 and agitating it, fine foreign matters contained in the secondary treatment water are agglomerated to form a sludge, and even a chromaticity can be adjusted.

The stirring pattern in the third stirring tank 50 may be performed in the same manner as the secondary stirring tank 40. [

The third treated water which has been stirred through the third stirring tank 50 drops downward when the discharge pipe 55 is opened and a fourth screen tank 61 is installed below the third stirring tank 50 The sludge contained in the tertiary treatment water discharged from the tertiary stirring tank 50 is filtered by the fourth screen tank 61 and is discharged to the outside, and only the tertiary treatment water passes through the fourth screen tank 61, And is contained in the outermost sedimentation tank (60).

The third-order treated water having passed through the fourth screen tank (61) is introduced into the outermost sedimentation tank (60) of the settling section, and the sludge which has not been subjected to the untreated treatment and the third- The sludge is directly precipitated from the above-described treated water inflow mold 62 and the treated water in a cleaner state flows through the lower portion of the treated water inflow mold 62 to the sidewalls of the settling tank 60 and the treated water inflow mold 62 The relatively clean upper layer water flows into the next step sedimentation tank 60 through the inlet 63 again and the same operation is repeated according to the number of the settling tank 60. [

In this process, all the fine sludge contained in the tertiary treatment water can be settled, and the sludge collected at the bottom of each settling tank 60 periodically or intermittently opens the valve under each settling tank 60, 65 to the outside.

Since the size of each of the settling tanks 60 gradually increases from the settling tank 60 located at the forefront with respect to the direction of movement of the tertiary treatment water toward the rear side of the settling tank 60, 60), the flow rate is slowed as the volume is increased, so that the sludge is not broken and the sedimentation efficiency can be improved.

At the inlet port 63 of each treatment water inflow frame 62, there are formed a plurality of desiccation screens 66, so that fine foreign matter and sludge components included in the treated water when the tertiary treatment water is moved through the screen 66 The sludge component is caught through each sieve 66 so that the sludge concentration inside the sieve 66 is increased but the sieve of the sieve 66 is not blocked by the sludge So that the flow of the tertiary treatment water is not disturbed. When the sludge concentration in the sieve 66 is saturated, the sieve 66 is removed to remove the sludge.

The tertiary treatment water moved to the final settling tank 60 flows into the filter unit 70 in accordance with the pumping of the underwater pump 67. In the course of passing through the multi-stage filter, the tertiary treatment water, Sludge or the like is filtered through the filter unit 70 and the cleaned final treated water can be discharged as it is or pumped to the final treated water receiving tank 20 so that it can be reused for singer use.

Since the fresh water capacity of the filter unit 70 is made larger than the capacity of the final settling tank 60 of the settling unit, the tertiary treatment water can pass through the filter unit 70 without any delay, There is also an advantage of being enabled.

At this time, although not shown in the drawing, the final treated water that has passed through the filter unit to remove the high-concentration nitrogen compound has a structure in which a constant current generator is installed in a part of the final storage tank, And an electrolytic method for removing acidic nitrogen, ammonia nitrogen, and salinity by electrolysis.

In the existing electrolysis method, there is electrochemical denitrification method applying oxidation-reduction reaction between ammonia nitrogen and hypochlorous acid. When treating high concentration chloride ion solution in seawater, more than 10% of ammonia nitrogen is oxidized to nitrate nitrogen It is known to remain. The chloride ions contained in the treated water finally treated are oxidized to the positive electrode in the electrode to generate chlorine gas. The chlorine gas reacts with water to generate hypochlorous acid, which acts as a sterilizing agent. The electrode plate used here is made of a material having a high strength such as carbon steel, a small thermal conductivity and a low thermal expansion coefficient, a high efficiency of electrolytic reduction, and a material capable of enhancing reaction characteristics and corrosion resistance by facilitating the role of a catalyst.

On the other hand, when a vibrator 77 is installed in each of the screen tanks 12, 42, 61, and 81 so that waste water or treated water passes through the screen tanks 12, 42, 61, The lower surface of the second screen group to the fourth screen group 42, 61, and 81 is inclined toward one side or the central part, and at the lowermost part of the inclined part, So that the treated water having passed through the second to fourth screen sets 42, 61, and 81 can be collected and transferred to the next step accurately.

A guide plate 78 or a brush is provided at the discharge end of the screen conveyor 73 of the second to fourth screen groups 42 to 61 to form a second screen group to a fourth screen group 42) 61 (81) can be smoothly separated through the guide plate (78) or the brush, and this sludge joins at the final sludge conveying screen group, not shown in the drawing, (Not shown). In the dewatering tank, water is dewatered from the sludge, and the dewatered sludge is discarded or compressed to be utilized as fuel.

After all the work is completed, the mixing tank 10, the final treatment water receiving tank 20, the supplementary water receiving tank 90, each stirring tank 30, 40, 50, secondary treatment water storage tank (80) ), The foreign matter stuck to every corner of each of the screen tanks 12, 42, 61 and 81 is discharged to the respective washing water nozzles 17, 27, 37, 47, 57 and 79. (87) (97) can be removed through the water spray, the cleaned water is mixed tank 10, the final treatment water receiving tank 20, supplement water receiving tank 90, each stirring tank 30 Discharge pipes 19, 29, 35, 45, 55, 99 of the 40, 50 can be discharged to the outside.

The water that has cleaned each of the screen tanks 12, 42, 61, and 81 flows into the mixing tank 10 or collects in one place on the lower surface thereof to be collected in the secondary stirring tank 40, And then discharged to the outside through the discharge pipe 45 of the secondary agitation tank 40 and the sludge discharge pipe 65 of the sedimentation tank 60. The secondary treatment water storage tank 80 are sloped to one side and the underwater pump 82 is provided at the lower end thereof so that the entire amount of the cleaned water is pumped to the third agitation tank 50 through the underwater pump 82, Through the discharge pipe (55) of the discharge pipe (55).

In other words, after all the work is completed, all the components can be cleaned, and the cleaned water can be discharged to the outside.

As described above, the wastewater coagulation apparatus according to the present invention can be used in a wastewater coagulation apparatus in which wastewater, treated water, and coagulant are automatically introduced and passed through a multistage stirring tank 30, 40, It is possible to increase the efficiency of wastewater treatment. Further, the stirring vessels 30, 40, and 50 constituting the stirring unit are arranged vertically, A plurality of stirring vessels 30, 40 and 50 constituting a stirring part, a plurality of settling vessels 60 constituting a settling part and a plurality of screen sets 12, 42, 61 and 81 constituting a screen part So that a compact device can be realized.

In addition, in the treatment of high-concentration wastewater with a large load of pollution, odor is generated in the process of inputting the initial wastewater. Such odor gradually disappears as the coagulant, the replenishing water and the final treated water are added and stirred, Since the lid is hermetically sealed by the lid 10, it is possible to suppress the generation of odor. In some cases, the primary stirring tank 30 may be provided with a sealing lid.

In the case of wastewater treatment such as food wastewater which has a very high pollution load, a mixing tank is additionally installed and the mixing tank A and the mixing tank B are installed. The low-treated water is collected in a container-shaped storage tank and pumped to a primary stirring tank, and treated in the same manner as the above-mentioned treatment method.

10: mixing tank 11,41,51: flocculant feeder
12: first screen group 13, 33, 43, 53:
14, 34, 44, 54: stirring wing 15: waste water supply pipe
16, 22, 67, 82, 94: Submersible pump 20:
21: final treated water inlet pipe 30: primary stirring tank
31: Primary stirring vessel A 32: Primary stirring vessel B
19, 29, 35, 45, 55, 99: discharge pipe 36, 46, 56:
17, 27, 37, 47, 57, 79, 87, 97: wash water nozzle 40:
42: Second screen tank 50: Third stirring tank
60: settling tank 61: fourth screen
62: Process water inlet frame 63: Inlet port
65: sludge discharge pipe 66:
70: Filter part 73: Screen conveyor
74: drive roller 75: driven roller
76: conveying pipe 77: vibrator
78: guide plate 80: secondary treated water storage tank
81: Third screen group 90: Supplemental water tank
91: replenishing water inlet pipe 92: fifth screen tank
93: the sixth screen assembly

Claims (16)

When the wastewater is supplied, the solid material and the liquid material are separated, and the solid material is discharged to the outside. When the coagulant is charged with the liquid material only, the mixture is stirred through the stirring wing.
A final treated water receiving tank containing the final treated water relatively cleaned as compared with the wastewater;
A replenishment tank containing groundwater or clean water;
When the waste water, the final treated water, and the supplemental water flows from the mixing tank, the final treated water receiving tank, and the supplemental water receiving tank, the stirring water is agitated through a stirring blade to form a floc through condensation of foreign matters, thereby generating sludge. Agitated portion made;
A sedimentation unit having a plurality of sedimentation vessels continuously receiving the water introduced from the agitation unit to sediment the sludge contained therein and overflowing only the water on the upper side to the next stage;
Separating the solid matter from the liquid matter in the wastewater flowing into the mixing tank, separating the sludge in the treated water flowing from each of the stirring vessels of the stirring section into the stirring vessel of the next step from the treated water, A screen portion comprising a plurality of screen tanks installed between respective portions for separating the sludge in the water from the treated water; And
The pumped water from the last settling tank of the settling unit flows into the multi-stage filter to remove the fine sludge component contained in the treated water, and the final treated water is discharged or pumped to the treated water receiving tank to be reused And a filter unit. The method of claim 1,
The mixing tank has a coagulant feeder capable of quantitatively injecting coagulant on one side of the mixing tank, and a driving motor is fixed to the upper center portion, and stirring blades are mounted on upper and lower shafts of the driving motor, respectively, before the stirring operation through the stirring portion. It is configured to pretreat the waste water through the waste water and the flocculant stirring of the stirring blade, the lower surface is inclined toward one side or the center portion, the discharge pipe having a valve is connected to the lowermost position of the inclined portion;
The final treated water receiving tank and the supplemental water receiving tank are each configured to have a lower surface inclined toward one side or a central portion, and a discharge pipe having a valve is connected to a lowermost position of the inclined portion, respectively. The method of claim 1,
The stirring part
A primary agitating tank which generates sludge by agitating these waste water pretreated from the mixing tank and the final treated water and supplemental water from the final treated water receiving tank and the supplemental water receiving tank, respectively, to form flocs through agglomeration of foreign substances;
Sludge is disposed under the primary stirring tank in a state in which the volume of the primary stirring tank is 2 to 2.5 times larger than that of the primary stirring tank, and is discharged to the outside by filtering through the screen tank. A secondary stirring tank which introduces only the first treated water, and further adds and stirs the flocculant, the final treated water, and the supplemental water to form flocs through agglomeration of foreign substances to generate sludge; And
The volume of the sludge in the secondary treatment water discharged from the secondary agitation tank is larger than the primary agitation tank by 2 to 2.5 times. The sludge is filtered through the screen tank and discharged to the outside. And a third agitating tank for forming sludge by forming a flock. The method of claim 3, wherein
The primary stirring tank is composed of two primary stirring tank A, the first stirring tank B, the mixing tank, the final treatment water receiving tank, the point at which the stirring process in the first stirring tank A 60 ~ 80% proceeds A wastewater flocculation treatment device, characterized in that the wastewater, the final treated water, and supplemental water from the make-up water tank are mixed and introduced into the first stirring tank B and stirred. The method of claim 3, wherein
And a coagulant feeder for supplying a fixed amount of a coagulant to the mixing tank, the second agitating tank, and the third agitating tank, respectively. The method of claim 3, wherein
In the case of a large-scale processing facility, each of the stirring vessels is provided with a plurality of driving motors having a central portion and an equilateral angle around the central portion, and stirring vanes are mounted on the axes of the respective driving motors, And the wastewater, treatment water and make-up water in each of the stirring tanks are agitated with a flocculating agent, and each of the stirring vanes is mounted in a direction of guiding water flow downward, And is configured to rotate in a direction opposite to the stirring wing of the other portion while being mounted in the opposite direction. The method of claim 3, wherein
The stirring vessel is formed in a rectangular shape, and each of the stirring vessels has a protrusion formed so that the mixing direction of the wastewater, the final treated water, and the replenishing water rotates according to the rotation of the stirring blade is changed to generate a vortex. Wastewater flocculation treatment device characterized in that. The method of claim 1,
The settling portion includes:
The treatment water inlet frame through which the upper and lower portions penetrate is spaced apart from the outer wall and the lower surface of each of the settling tanks, and an inlet is formed in the inlet of the treated water inlet frame from the settling tank of the agitator or the previous stage to form the inlet. Or the water overflowed from the settling tank of the previous stage is introduced into each of the treated water inlet frame, the inlet is connected to the outer wall of each settling tank so that only the upper side water of the inflowed water to the next stage The lower surface of each settling tank is inclined toward the central portion or one side to collect the sludge, and the sludge discharge pipe is connected to the bottom of the inclined portion so that the sludge discharge pipe is discharged downward. Processing unit. The method of claim 8,
Wherein each of the settling basins is formed such that the volume gradually increases toward the rear with reference to the moving direction of the treated water. The method of claim 8,
Wherein each of the settling tanks is formed with a tug net at the inlet of the treatment water inflow frame. The method of claim 3, wherein
The screen unit includes:
A first screen tank provided at an upper portion of the mixing tank so as to be inclined to separate solid matter from wastewater flowing into the mixing tank from a liquid material; A second screen tank provided between the primary agitation tank and the secondary agitation tank so as to be inclined to separate sludge contained in the primary treatment water from the primary treatment water; A third screen tank installed at an angle between the secondary agitator and the tertiary agitator to separate the sludge contained in the secondary water from the secondary water; And a fourth screen set sloped between the third stirring tank and the settling section for separating the sludge contained in the third treated water from the third treated water. The method of claim 11,
Wherein each of the screen groups has a screen conveyor connected between a driving roller and a driven roller, the driving roller being connected to the driving motor so as to be able to transmit power so that the screen conveyor is driven by the driving roller, The wastewater or each treatment water is configured to pass downward while the solid matter or sludge is conveyed to the outside while continuously rotating between the driven rollers;
The lower portion of the screen conveyor of the second to fourth screen tank is configured to be inclined in one direction to collect each treatment water, the lowermost part of the inclined portion is connected to the transfer pipe for transferring the collected water to the next step ;
A vibrator is installed on one side of each of the screen tanks so as to smoothly separate the sludge from the treated water;
A guide plate or a brush is installed at a screen conveyor discharge end of each of the screen sets to separate sludge filtered by the screen conveyor from the screen conveyor;
And a washing water nozzle rotatable by 360 ° for removing the sludge from the screen conveyor is provided at an upper side of each of the screen tanks and the washing water nozzle is connected to a final treated water inflow pipe or a makeup water inflow pipe Wherein the wastewater coagulation treatment apparatus comprises: 13. The method of claim 12,
Wherein a final sludge conveying screen is further provided so that the sludge separated through the guide plate or the brush provided at the screen conveyor discharge end of each screen group can uniformly be sent to the dehydrator. The method of claim 11,
The second stirring tank and the third stirring tank are arranged in parallel, the third screen tank is provided below the secondary stirring tank, and the lower surface of the second screen tank is inclined in one direction so as to collect the secondary treated water to one side. Wherein a storage tank is provided below the third screen tank and an underwater pump is disposed at the lowermost portion of the inclined portion of the secondary treatment water storage tank so as to allow the secondary treatment water to flow into the tertiary stirring tank. Coagulation treatment device. 15. The method of claim 14,
The mixing tank, the final treatment water holding tank, the supplemental water holding tank, the respective stirring tank, the secondary treatment water storage tank is not discharged together with the treated water, the mixing tank, the final treatment water holding tank, the 360 ° rotatable washing water nozzles are installed to clean the foreign matter trapped in the inner corners of the supplementary water tank, the respective agitating tanks and the secondary treated water storage tank, and the foreign matters on the agitating blades through water spraying. The washing water nozzle is wastewater coagulation treatment apparatus, characterized in that made in connection with the final treated water inlet pipe or supplemental water inlet pipe. The method of claim 1,
A final storage tank in the form of a tank or a water tank for storing final treated water that has passed through the filter unit to remove high concentration nitrogen compounds in the final treated water just before discharge, and a constant current generator installed in a part of the final storage tank, The chloride ions contained in the treated water finally treated in the final storage tank are oxidized to the positive electrode of the electrode of the constant current generator to generate chlorine gas and the chlorine gas reacts with water to generate hypochlorous acid, And a denitration device for removing nitrate nitrogen, ammonia nitrogen, and salt in the final treated water by generating a constant current by electrolysis to generate electrolysis.

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