KR101964832B1 - Water treatment apparatus - Google Patents

Abstract

The present invention relates to a floating separation water treating apparatus with improved processing efficiency, which comprises: a stirring unit (100); a floating precipitation tank (200); a pressurized water supply unit (300); a scum removing unit (400); a slurry removing unit (500); and a treated water collecting unit (600).

Description

{WATER TREATMENT APPARATUS}

The present invention relates to a floating separation water treatment apparatus, and more particularly, to a floating separation water treatment apparatus capable of improving treatment efficiency of raw water.

In general, water treatment methods including pollutants such as sewage, wastewater and water purification include biological treatment methods and physico-chemical treatment methods. Recently, there are limitations on the biological treatment methods, and the development of the physico-chemical methods is being actively carried out.

These physicochemical treatment methods include various methods such as pressurization, filtration, precipitation, ultraviolet disinfection, ozone disinfection, and chlorine disinfection. Among these various physico-chemical methods, pressurized flotation methods which are advantageous in terms of treatment efficiency and economy are widely used.

Here, the pressurized floatation method and apparatus for pressurizing gas to generate pressurized water and treating the contaminants using the generated pressurized water are configured in various forms to treat contaminants. Various physicochemical and control measurement methods are applied to the pressurized flotation device, and each element technology is combined and operated in a single treatment mode to treat the pollutant.

In this connection, Korean Patent No. 10-0606555 (filed on July 21, 2006) discloses a multifunctional high-efficiency government phase separation water treatment apparatus and purification method through a combination of ozone flotation and granular activated carbon filtration.

Conventional pressurized flotation methods and devices as disclosed use scrapers to remove sludge generated after processing. At this time, the scraper is moved in a closed chain rotating chain.

Both ends of the chain are coupled to the driving pulley and the driven pulley, and the driving pulley receives the driving force from the driving motor and rotates. Since the driving motor is disposed outside the floatation settling tank and the driving pulley is located inside the floatation settling tank, the power transmission means is coupled to the driving pulley through the floatation settling tank for power transmission.

When the transmission means is coupled through the floatation tank, there is a risk of leakage and the packing is used to maintain the airtightness. When packing is used, there is a problem that management cost is increased due to power loss due to friction and replacement of periodical consumables.

Conventional pressurized floatation methods and apparatuses, on the other hand, have a problem in that, after the pressurized water containing bubbles is supplied as the water to be treated, the contaminants float in a state where the water to be treated and the bubbles are not sufficiently mixed, And the treatment efficiency is lowered.

On the other hand, a scum removing unit is provided to remove floating contaminants floating on the water surface, that is, scum. In the scum removing portion, the scum scraper moved along the chain forcibly moves the scum and discharges it to the outside.

However, in the conventional scum scraper, after the scum is moved, the scum scraper can not properly discharge the scum into the scum discharging tank, and a part of the scum scraper is moved to the floatation tank again. That is, the scum scraper can not properly scrape the scum and discharge it to the scum discharging tank, and the scum may be discharged to the space between the scum scraper and the floating sedimentation tank.

In addition, the scum discharged to the scum discharging tank has a disadvantage that the weight of the scum is low because it is a floating material in a bubble state containing a large amount of air, thereby increasing the processing cost and lowering the dehydration efficiency when the dehydration process is performed.

It is an object of the present invention to provide a floating separation water treatment apparatus which can dispose a driving transmission means of a sludge removing unit so as to be spaced apart from each other with a floatation settling tank interposed therebetween, .

Another object of the present invention is to provide a floating separation water treatment apparatus capable of quickly and uniformly mixing a treatment object water and pressurized water by forming a pressurized water injection nozzle in the form of a venturi tube.

Another object of the present invention is to provide a floating separation water treatment apparatus which can remove the floating substances induced in the treatment target water as much as possible by delaying the floating speed of the pressurized water and the water to be treated.

It is still another object of the present invention to provide a floating separation water treatment apparatus capable of improving the scum removing efficiency of scrubbing rejection.

Another object of the present invention is to provide a flotation water treatment apparatus capable of improving the dewatering efficiency by blowing air bubbles contained in a scum when scum is discharged.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

The object of the present invention can be achieved by a floating separation water treatment apparatus. The floatation water treatment apparatus of the present invention comprises: a stirring part (100) which stirs a medicine with raw water to produce a floc-formed treatment object water in which contaminants aggregate; A floatation sedimentation tank 200 for separating the water to be treated generated in the agitation unit 100 into floc scum and treated water; A pressurized water supply unit 300 provided at a lower portion of the floatation settling tank 200 to supply pressurized water containing minute bubbles to float the floc; A scrubber (400) provided on the floatation settling tank (200) to remove the scum; A sludge removing unit 500 provided at a lower portion of the floatation settling tank 200 to remove sludge deposited on a bottom surface of the floatation settling tank 200; And a treatment water collecting unit 600 for collecting the treated water separated from the scum in the floatation settling tank 200. The sludge removing unit 500 includes a sludge separation unit 200, A sludge collector chain 530 connected to the collector driving pulley 510 and the sludge collecting machine driving pulley 520 in a closed loop manner and rotated; A sludge scraper 550 coupled to the sludge collector chain 530 to move the sludge while moving; And a sludge collector driving motor 540 for generating a rotating force for rotating the sludge collector driving pulley 510 from the outside of the floatation settling tank 200. The sludge collector driving pulley 510 is connected to the sludge collector driving motor The first and second magnetic gears 511 and 543 are spaced apart from each other with the floatation settling tank 200 interposed therebetween.

The first magnetic gear 511 and the second magnetic gear 543 may include a plurality of first permanent magnets 511a and a plurality of second permanent magnets 543a disposed along the circumferential direction, And the second permanent magnets 543a facing the first permanent magnets 511a are arranged so that their polarities are opposite to each other, The gear 511 can be rotated.

According to one embodiment, the pressurized water supply unit 300 includes a pressurized water circulation pump 330 for supplying the treated water collected in the treated water collection unit 600; An air contact tank 340 for mixing pressurized water supplied from the pressurized water circulation pump 330 with compressed air to form pressurized water; And a pressurized water injection nozzle (310) disposed below the floatation settling tank (200) for injecting pressurized water containing fine bubbles into the floatation settling tank (200), wherein the pressurized water injection nozzle (310) The pressurized water injection nozzle 310 corresponding to the venturi neck 316a in which the pressurized feeding passage 316 is formed narrowly is formed on the outer wall surface of the pressurized water injection nozzle 310, A plurality of water feeding holes 315 for introducing the water to be treated into the pressurized feeding passage 316 and inducing mixing with the micropore may be formed.

According to an embodiment of the present invention, the stirring part 100 and the floatation settling tank 200 are partitioned by a third partition 220 having a third flow path 221 formed thereunder, and the pressurized water injection nozzle 310 The bottom of the floatation settling tank 200 in which the pressurized water injection nozzle 310 is located is located on the movement path of the water to be treated through the third flow path 221 and is sprayed from the pressurized water injection nozzle 310 A guide wall 230 for guiding a flock floated by minute bubbles to the water surface is formed in a predetermined length in the upward direction and an inclined guide wall 230 is formed at an upper end of the guide wall 230 so as to be inclined at a predetermined angle 231 may be provided.

According to an embodiment of the present invention, between the third partition 220 and the guide wall 230, there are horizontally disposed at mutually different heights in directions opposite to each other to delay the floating speed of the object water and the minute bubbles A plurality of baffles 240 may be provided.

According to one embodiment, the sprayer 400 is coupled to the scum remover driving pulley 410 and the scum removing machine pulley 420 spaced apart from each other in an upper part of the floatation settling tank 200 in a closed loop form A rotating scum remover chain 430; A plurality of scum-coupled pieces 440 coupled to the scum remover chain 430; And a scum scraper 450 for scraping off the scum while the scum is moved together with the same piece 440. The scum scraper 450 is disposed on the same side as the scum 440, The second scum scraper 453 positioned rearward with respect to the rotating direction of the pair of scum scraper 450 is provided with a pair of first scum scraper 453 451, respectively.

According to one embodiment, the comb descender 400 further includes a scum collecting tank 470 disposed at one side of the scum remover driving pulley 410 to collect scum moved by the scum scraper 450 And a plurality of bubble removing mesh nets 471a, 471b, and 471c disposed at different heights above the scum collecting tank 470 to bubble air bubbles contained in the scum may be provided.

The floatation water treatment apparatus according to the present invention includes a plurality of baffles formed in a horizontal direction on a path where the water to be treated floats on the floor of the floatation sedimentation tank to delay the floatation rate of the pressurized water and the treatment object water. In this process, the contact time of the flocs of the object water to be treated and the minute bubbles of the pressurized water is increased, and the flotation efficiency of the flocs contained in the object water can be improved. Thus, the processing efficiency with respect to the number of objects to be treated can be improved.

In addition, the floating separation water treatment apparatus according to the present invention is characterized in that the internal flow path of the pressurized water injection nozzle is formed in the form of a venturi tube, the external target to be treated is sucked into the pressurized water injection nozzle by the high- And then discharged together. This makes it possible to quickly mix the number of objects to be treated and the pressurized water and to mix a large number of objects to be treated with the pressurized water evenly. The possibility of even mixing of the pressurized water and the object water to be treated can lead to an improvement in the treatment efficiency with respect to the object water to be treated.

Meanwhile, in the floatation water treatment system according to the present invention, the scum scraper of the scratch rejection structure is formed in a double structure, and the second scum scraper at the rear is formed longer than the first scum scraper at the front. As a result, the scum that has escaped from the first scum scraper at the front is scratched again by the second scum scraper and is discharged to the outside, so that the scum processing efficiency can be improved.

Further, a plurality of bubble removing mesh nets are provided on the discharge path of the scum, and the bubbles contained in the scum are blown out to the outside. Thus, the dewatering efficiency can be increased in the dewatering process of the scum discharged to the outside.

The floatation water treatment apparatus according to the present invention uses magnetic gears as transmission means for driving a sludge removal unit for removing sludge. The magnetic gears are arranged apart from each other with the floatation settling tank therebetween, and transmit the driving force by the magnetic force of the permanent magnets. Thereby, there is an advantage that the risk of leakage is eliminated and the power loss can be reduced compared with the case where the driving force is transmitted physically.

1 is a front view showing an overall configuration of a floating separation water treatment apparatus according to the present invention,
2 is a plan view showing a planar configuration of a floating separation water treatment apparatus according to the present invention,
FIG. 3 is an exemplary view showing a process of mixing water to be treated and pressurized water in the floating separation water treatment apparatus according to the present invention, FIG.
4 is a view showing a configuration of a pressurized water jetting nozzle of a floating separation water treatment apparatus according to the present invention,
FIG. 5 is a side view showing a side structure of a floating separation water treatment apparatus according to the present invention,
6 is a diagram showing the configuration of squash rejection of the floating separation water treatment apparatus according to the present invention,
FIG. 7 is an exemplary view showing a scum removing process of the scum control unit of the floating separation water treatment apparatus according to the present invention,
8 is a view showing the construction of the sludge removing unit of the floating separation water treatment apparatus according to the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

Fig. 1 is a front view showing a frontal structure of a floating separation water treatment system 1 according to the present invention, and Fig. 2 is a plan view showing a planar construction of a floating separation water treatment system 1. Fig.

As shown in the figure, the floating separation water treatment apparatus 1 according to the present invention processes raw water (not shown) by using a dissolved air flotation (DAF). Dissolved Air Flotation (DAF) is a water treatment method based on the principle that minute bubbles generated when air is saturated with pressurized water instantaneously are floated on flocs and separated from raw water.

To this end, the floatation water treatment system 1 of the present invention comprises a stirring part 100 for generating a treatment object water W by stirring the medicine A with raw water (not shown) A floatation settling tank 200 for separating the object W to be treated into contaminants and treated water W1 and a pressurized water supply unit 300 provided in the floatation settling tank 200 for supplying pressurized water B to float contaminants, A scrubbing unit 400 disposed at an upper portion of the floatation settling tank 200 to remove floated contaminants (scum), and a scrubber 400 disposed at a lower portion of the floatation settling tank 200 to be settled on the bottom surface of the floatation settling tank 200 A sludge removing unit 500 for removing the sludge D and a treated water collecting unit 600 for collecting treated water W1 separated from contaminants in the floatation settling tank 200.

 The contaminants to be treated in the floatation water treatment apparatus 1 of the present invention include floc, sludge, scum and the like, and the object of the contaminant is not limited thereto. Floc refers to contaminants generated in the raw water by the mixing of raw water and chemicals, sludge refers to contaminants that settle on the bottom surface of the floatation settling tank 200, and scum refers to contaminants that float to the surface by microbubbles.

The agitating unit 100 stirs the chemical (A) and the raw water to generate a treatment target water W. Here, the treatment target number W refers to raw water in which flocs are generated due to agitation of the drug (A) and raw water. The stirrer 100 includes a reaction mixer 110 for rapidly mixing the raw water supplied from the rapid mixing unit 110 and raw water supplied from the rapid mixing unit 110 by injecting the drug A into the raw water and rapidly mixing the raw water with chemicals, And an agglomeration tank 130 for agitating the raw water supplied from the water supply unit 120 and the chemicals to be agglomerated.

The raw milk feed pipe 111 and the drug feed pipe 113 are connected to the rapid mixing tank 110, respectively. The raw milk feed pipe 111 supplies raw water to the rapid mixing tank 110 and the drug feed pipe 113 supplies the drug A. [

The drug (A) used in the floatation-water treatment apparatus (1) of the present invention is generally used as a coagulant of aluminum sulfate, PAC, iron sulfate and polymer, and caustic soda, chemicals for controlling pH such as sulfuric acid, Can be injected. At this time, the amount of the medicine to be injected may be automatically adjusted by the automatic measuring instrument installed in the floatation settling tank 200 or the final discharge area.

The medicine supply pipe 113 is connected to the medicine storage tank 113a and the medicine pump 113b is provided between the medicine supply pipe 113 and the medicine storage tank 113a.

In the medicine supply pipe 113, a rapid stirrer 115 is installed for rapid mixing of the drug (A) and raw water. The rapid agitator 115 is rotatably provided in the center region of the rapid mixing tank 110 to mix the drug A and raw water (not shown). The rapid stirrer 115 is provided with a stirring shaft 115a and a stirring pawl 115 which is coupled to the lower portion of the stirring shaft 115a and rotates together with the stirring shaft 115a and mixes the medicine A and raw water (115b) for rotating the stirring shaft (115a), and a stirring motor (115c) for rotating the stirring shaft (115a).

The reaction tank 120 is provided adjacent to the rapid mixing tank 110 so that raw water supplied from the rapid mixing tank 110 reacts with chemicals to form a treatment target water W. In the rapid mixing tank 110, the raw water and the drug (A) are overflowed and supplied to the reaction tank (120).

In the reaction tank 120, a first slow stirrer 121 for mixing the raw water and the drug (A) to accelerate the reaction is provided. The construction of the first full-speed stirrer 121 is the same as that of the rapid stirrer 115 described above.

The flocculation tank 130 causes flocs to be generated in the treatment target water W in which the raw water and the drug A are mixed. The object water W in the reaction tank 120 is moved to the flocculation tank 130 through the first flow path 125a under the first partition wall 125. [

The flocculation tank (130) is provided with a second slow stirrer (131) for inducing the generation of flocs by stirring the water to be treated (W). The object water W of the flocculation tank 130 is moved to the floatation sedimentation tank 200 through the second partition 210.

The water to be treated supplied from the rapid mixing tank 110 is supplied to the upper part of the reaction tank 120 and flows downward from the upper part to the lower part through the sidewalls 117 formed on one side surface, Is supplied to the lower portion of the flocculation tank 130 along the first flow path 125a under the first partition wall 125 and is moved upward from the lower portion.

Since the stirrers 115, 121 and 131 are provided in the rapid mixing tank 110 and the reaction tank 120 and the flocculation tank 130, a large number of organic substances are agglomerated in the flocc, .

The floatation settling tank 200 separates the object water W generated in the agitator 100 into contaminants (scum and sludge) and treated water W1. 2, the floatation settling tank 200 is separated by the agitating portion 100 and the third partition 220 and the third flow path 221 is formed at the lower portion of the third partition 220, The number W is supplied.

The floatation settling tank 200 is provided with a guide wall 230 and a baffle 240 and a pressurized water supply unit 300 is provided below the floatation settling tank 200. The floatation settling tank 200 delays the floating time of the pressurized water B supplied from the pressurized water supply unit 300 and the process target water W to remove the suspended solids contained in the treated water W as much as possible .

3 is an exemplary view showing a process in which the pressurized water B and the treatment target water W are mixed in the floatation sedimentation tank 200.

As shown in FIG. 3, the floatation settling tank 200 is provided with a third bank 220 and a third flow path 221 which are separated from the agitating unit 100 by a predetermined distance. The object water W in the flocculation tank 130 is moved down through the second flow path 211 in the upper part of the second bank 210 and flows through the third flow path 221 in the lower part of the third bank 220 Contacted with the pressurized water spray nozzle 310 of the pressurized water supply unit 300, and then moved upward along the guide wall 230.

The pressurized water injection nozzle 310 is disposed at the bottom of the floatation sedimentation tank 200 between the third partition 220 and the guide wall 230. The processing target water W moved through the third flow path 221 is brought into contact with the pressurized water B which is supplied to the pressurized water injection nozzle 310 to be supplied with the pressurized water B, . At this time, a plurality of baffles 240 are arranged in the horizontal direction in the movement path of the process target water W between the third partition 220 and the guide wall 230

The plurality of baffles 240 are arranged in a zigzag form in the horizontal direction on the third partition 220 and the guide wall 230, respectively. In the floating separation water treatment apparatus 1 according to the preferred embodiment of the present invention, the four baffles 240 are formed in opposite directions to each other, but this is only an example, and the number of the baffles 240 can be increased or decreased.

The plurality of baffles 240 blocks the movement path of the process target water W and delays the time when the process target water W and the pressurized water B are mixed and floated. That is to say, in the space between the third partition wall 220 and the guide wall 230, the time for which the process target water W and the pressurized water B are in contact with each other is increased so that the minute bubbles contained in the pressurized water B are sufficiently processed And is mixed with the target number (W) to float the floating material contained in the target number (W).

As a result, the pollutant treatment efficiency of the object water W can be improved.

Here, the guide wall 230 is vertically formed up to a certain height, and an inclined guide wall 231 is formed at an upper portion of the guide wall 230 so as to be inclined at a predetermined angle.

The inclined guide wall 231 is formed to be inclined at a certain angle?. The inclination angle? Of the inclined guide wall 231 is formed at an angle of 50 to 80 degrees. The inclined guide wall 231 guides the fine bubbles floating along the guide wall 230 naturally upward. That is, the microbubbles rise along the flow direction of the object water W, and the inclined guide wall 231 is inclined at an angle of 50 to 80 degrees to prevent the flock from colliding with the inclined guide wall 231 to break.

Also, the inclined guide wall 231 serves to separate the clean water W1 from the scum C floating on the water surface. That is, the scum C is positioned above the upper end of the inclined guide wall 231, and the clean treated water W1 is located below the upper end.

The pressurized water supply unit 300 is provided at a lower portion of the floatation settling tank 200 and supplies pressurized water B of high pressure containing minute bubbles so that contaminants contained in the water to be treated float. The pressurized water supply unit 300 is connected to the pressurized water injection nozzle 310 for supplying the pressurized water B from the lower part of the floatation sedimentation tank 200 and the first treated water discharge pipe 621 of the treated water collection tank 620 Which circulates the treated water W1 to circulate the treated water W1 in the first treated water discharge pipe 621 and the air in the air contact tank 340, An air contact tank 340 for contacting the treated water W1 with air and forming pressurized water containing air bubbles and a pressurized water supply unit 340 for distributing the pressurized water B to the plurality of pressurized water spray nozzles 310 And a pressurized water supply pipe 360 for supplying the pressurized water B of the air contact tank 340 to the pressurized water supply pipe 370. [

 The treated water W1 collected in the treated water collecting unit 600 is circulated and recycled to form the pressurized water B. The first treated water discharge pipe 621 of the treated water collecting unit 600 is connected to the treated water circulating pipe 320 and the required amount of treated water W1 is supplied to the treated water treating pipe 320 As shown in Fig.

The air supplied from the air compressor 350 and the treated water W1 flowing through the treatment and recovery pipe 320 are mixed in the air contact tank 340 by driving the circulation pump 330. [ In the air contact tank 340, pressure is applied together with a strong agitating force to divide the air into fine particles and dissolve in the treated water W1 to form the pressurized water B.

The pressurized water B of the air contact tank 340 is supplied to the pressurized water pipe 370 through the pressurized water supply pipe 360. 2, the plurality of pressurized water injection nozzles 310 are formed along the longitudinal direction of the pressurized water pipe 370. The pressurized water pipe 370 is formed along the lateral direction at the bottom of the floatation settling tank 200, Are formed at regular intervals.

4A is a perspective view showing the external configuration of the pressurized water spray nozzle 310, and FIG. 4B is a cross-sectional view showing a sectional configuration of the pressurized water spray nozzle 310. As shown in FIG.

4A, a pressurized water injection nozzle 310 according to the present invention includes a nozzle body (not shown) connected to a pressurized water supply pipe 360 and having an inflow hole 312 through which pressurized water B flows An upper casing 313 covering the upper portion of the nozzle body 311 and having a pressurized milk feeding passage 316 formed therein and an upper casing 313 formed to communicate with the pressurized milk feeding passage 316 on the outer peripheral surface of the upper casing 313, And includes a feeding breast 315 to be treated.

A pressurized milk feeding path 316 is formed between the inflow hole 312 and the ejection hole 317 of the pressurized water injection nozzle 310 as shown in FIG. 4 (b). A porous partition plate 314 is disposed inside the nozzle body 311. The pressurized water B flowing through the inflow hole 312 passes through the porous partition plate 314 and the solubility of the air becomes higher so that the amount of fine bubbles in the pressurized water B increases.

The pressurized feeding passage 316 formed on the upper part of the porous partition plate 314 is formed in the form of a venturi tube whose diameter gradually decreases and then increases again. The diameter of the venturi neck 316a is gradually reduced from the inflow hole first diameter R1 of the pressurized milk feeding path 316 to the second diameter R2 of the venturi neck 316a and the third diameter The diameter gradually increases to R3. At this time, the third diameter R3 is larger than the first diameter R1.

In this way, since the pressurized water feeding passage 316 is formed in the form of a venturi pipe, the moving speed of the pressurized water B is increased in the region of the venturi neck 316a, the pressure is increased, the diameter is increased in the discharge hole 317, do.

 At this time, since the venturi neck 316a forms a high pressure, the treatment target water W of the floatation sedimentation tank 200 having a relatively low pressure is sucked through the feeding breast 315 to be treated. The water W to be treated and the pressurized water B are mixed in the venturi neck 316a and discharged through the discharge hole 317. [

3, the processing target water W transferred to the floatation settling tank 200 through the second flow path 211 of the second partition 210 is supplied to the venturi neck 310 of the pressurized water injection nozzle 310, Is sucked into the feed breast 315 by the high pressure formed in the pressurized water injection nozzle 316a and mixed with the pressurized water B in the pressurized water injection nozzle 310 and then discharged through the discharge hole 317. [

Since the object W to be treated is discharged after being sucked and mixed with the pressurized water injection nozzle 310, the mixing ratio of the micro-fabric and the processing target water W is increased in the pressurized water injection process, and more uniform mixing is possible .

FIG. 5 is a side view showing a side construction of the floatation water treatment apparatus 1 according to the present invention, FIG. 6 is a view showing the structure of the float desorption apparatus 400, Fig.

The scratch rejection 400 removes contaminants, i.e., scum, floating by microbubbles in the floatation sedimentation tank 200. As shown in FIGS. 1 and 2, the smoke rejection receptacle 400 is formed so as to cover the upper surface of the floatation sedimentation tank 200 from the upper part of the inclined guide wall 231 and float on the inclined guide wall 231 Remove scum (C) by scraping.

The squeegee rejection system 400 includes a scum removing machine driving pulley 410, a scum removing machine driving pulley 410 and a scum removing machine driving pulley 410 arranged in a spaced relation to each other, A plurality of scum pieces 440 coupled to the scum remover chain 430 and a plurality of scum pieces coupled to the plurality of scion pieces 440 so that the scum is separated from the same piece 440, A scum scraper 450 which scatters the scum C on the water surface while being moved together with the scum scraper 450 and a scum scraper 450 which is provided on the side of the scum remover driving pulley 410 and which is moved by the scum scraper 450, (470).

The scum remover driving pulley 410 is coupled to the scum remover driving motor 460 and receives power from the scum remover driving motor 460 to rotate. The scum removing machine driving pulley 410 coupled to the scum remover chain 430 by the rotation of the scum remover driving pulley 410 is rotationally driven.

A plurality of scum-shaped copper strips 440 are provided on the scum-removing machine chain 430 at regular intervals. A scum scraper 450 is coupled to the scum-shaped copper strip 440. Here, the scum scrapers 450 are provided in pairs as shown in FIG. That is, the first scum scraper 451 and the second scum scraper 453 are provided in parallel with the scum 440. The first scum scraper 451 and the second scum scraper 453 are provided in the form of a blade having a large area to scrape and move the scum C.

At this time, the length (l2) of the second scum scraper 453 located rearward of the length (l1) of the first scum scraper 451 positioned forward with respect to the moving direction of the scum remover chain 430 is slightly longer .

The first scum scraper 451 and the second scum scraper 453 scrape the scum C floating on the water surface when the scum 440 moves along the scum remover chain 430, 470).

Since the length of the second scum scraper 453 is longer than that of the first scum scraper 451, the scum C which is pressed by the first scum scraper 451, (453) is scratched again.

Further, a scum scraper contact block 472 is formed above the scum collecting tank 470 so that the scum scraper 450 can recover the scum from the water. The upper surface of the scum scraper contact block 472 is formed to be inclined upward along the advancing direction of the scum scraper 450 and curved along the rotational curvature of the scum scraper 450. On the other hand, when the first scum scraper 451 scrapes the scum C to the scum collecting tank 470 and there is a scum that has passed between the upper surface of the scum scraper contact block 472 and the first scum scraper 451 And the second scum scraper 453 on the rear side again discharges the scum into the scum collecting tank 470.

Due to the structure of the scum scraper 450 having such a double structure, the scum removing efficiency can be significantly increased as compared with the conventional scrubber dispenser having a scum scraper.

The scum C discharged to the scum collecting tank 470 drops to the lower portion of the scum collecting tank 470 and is discharged to the outside through the scum discharging pipe 473 under the scum collecting tank 470. At this time, a plurality of bubble removing mesh nets 471a, 471b and 471c are provided on the path where the scum C is moved from the scum scraper contact block 472 to the scum discharge pipe 473 as shown in Fig.

The scum (C) floated on the floatation sedimentation tank (200) contains fine bubbles in many directions. The collected scum (C) is subjected to a dehydration process in a dehydration facility (not shown) to reduce the volume. However, if the scum C containing a large amount of bubbles is directly discharged to the scum discharge pipe 473 and sent to a dehydration facility (not shown), the bubbles interfere with the discharge of water and the dehydration efficiency is lowered.

The plurality of bubble removing mesh nets 471a, 471b and 471c are disposed in the discharge path of the scum C to break the bubbles contained in the scum C, thereby increasing the dewatering efficiency. The bubble removal mesh nets 471a, 471b and 471c are provided in a form having a mesh of fine size and the bubbles are blown as the scum C passes through the bubble removal mesh nets 471a, 471b and 471c.

The plurality of bubble removing mesh nets 471a, 471b and 471c are disposed at different heights on both side walls of the scum collecting tank 470 as shown in the figure. At this time, the respective bubble removing mesh nets 471a, 471b, and 471c are arranged in a zigzag form so as to be inclined downward.

The plurality of bubble removing mesh nets 471a, 471b and 471c are arranged so as to overlap with each other by a predetermined area in the middle area so that the scum C passes through the plurality of bubble removing mesh nets 471a, 471b and 471c, .

The sludge removing unit 500 is provided on the bottom side of the floatation settling tank 200 to remove precipitated contaminants accumulated on the bottom of the floatation settling tank 200, that is, the sludge D. Part of the flocs or pollutants in the floatation sedimentation tank 200 that are large in specific gravity and not mixed with the micro-sediment are settled at the bottom of the floatation sedimentation tank 200. The sedimented sludge can not be re-floated, so it accumulates on the floor and gradually increases the quantity of treated water (W1).

8 is a perspective view showing the structure of the sludge removing unit 500. As shown in FIG. 5 and 8, the sludge removing unit 500 includes a sludge collector driving pulley 510 and a sludge collecting machine driving pulley 520 spaced apart from each other, a sludge collector driving pulley 510, A sludge collector chain 530 connected to the pulley 520 in a closed loop manner and a plurality of sludge scraper 550 spaced apart from the sludge collector chain 530 and scraped off the sludge D, And a sludge collection tank 560 in which sludge D moved by the sludge scraper 550 is collected.

The sludge collector driving pulley 510 is rotated by receiving the driving force of the sludge collector driving motor 540. Here, the sludge collector drive pulley 510 is located at the bottom of the floatation sedimentation tank 200, i.e., in the water. The sludge removing unit 500 according to the present invention disposes the transmission means outside the floatation settling tank 200 without drilling the floatation settling tank 200 to drive the sludge collector driving pulley 510. [

5, the sludge collector driving pulley 510 is provided with a first magnetic gear 511 and the sludge collector driving motor 540 is provided with a second magnetic gear 543 on the driving shaft 541 . The first magnetic gear 511 and the second magnetic gear 543 are spaced apart from each other with an outer wall of the floatation settling tank 200 interposed therebetween.

The first magnetic gear 511 and the second magnetic gear 543 are driven by the magnetic force of the magnet and transmit the driving force of the sludge collector driving motor 540.

8, a plurality of first permanent magnets 511a are radially arranged on the outer wall surface of the first magnetic gear 511. As shown in FIG. At this time, the plurality of first permanent magnets 511a are positioned such that the polarities are alternately arranged along the circumferential direction. Namely, it is placed in the form of an N pole magnet, an S pole magnet, an N pole magnet, and an S pole magnet.

The plurality of second permanent magnets 543a are also disposed opposite to each other in the circumferential direction. When the second magnetic gear 543 is engaged with the first magnetic gear 511 with the floating settling tank 200 interposed therebetween in the state where the second magnetic gear 543 is coupled to the drive shaft 541, the first permanent magnet 511a and the second permanent magnet 511a, (543a) are positioned so that their polarities are opposite to each other. That is, the N pole magnets of the first permanent magnets 511a and the S pole magnets of the second permanent magnets 543a are opposed to each other.

In this state, when the sludge collector driving motor 540 is driven and the driving shaft 541 is rotated, the second magnetic gear 543 integrally coupled to the driving shaft 541 is also rotated. When the second magnetic gear 543 is rotated, the first magnetic gear 511 also rotates together with the magnetic force of the second magnetic gear 543. That is, the first magnetic gear 511 also rotates in conjunction with the rotation of the second magnetic gear 543 by the attractive force of the permanent magnets of different polarities.

Therefore, the sludge collector driving pulley 510 can be driven by receiving the driving force in a state where the sludge collector driving pulley 510 is separated from the floatation settling tank 200. As a result, it is possible to prevent the leakage phenomenon that occurs when the driving force is physically transmitted by piercing the floating sedimentation tank 200, the increase of the maintenance cost due to wear of the packing, and frequent replacement.

The sludge collector chain 530 is rotated in closed loop form between a sludge collector drive pulley 510 and a sludge collector type pulley 520 and a plurality of sludge scraper 550 moves along the sludge collector chain 530 The sludge (D) deposited on the bottom surface is scratched and moved.

The sludge D moved by the sludge scraper 550 is collected in the sludge collecting tank 560 and discharged to the outside.

The treated water collecting unit 600 is disposed above the sludge removing unit 500, and the treated water W1 from which contaminants are removed is collected. The treated water collecting unit 600 includes a plurality of treated water collecting pipes 610, a treated water collecting tank 620 that receives the treated water W1 collected through the treated water collecting pipe 610, W1) to adjust the level of the floatation sedimentation tank (200).

A plurality of treated water collecting pipes 610 are arranged in parallel to the lower portion of the floatation settling tank 200. A plurality of treated water feeding holes 611 are formed on the outer surface of the treated water collecting pipe 610. The treated water W1 collected through the treated water collecting pipe 610 is collected in the treated water collecting tank 620. The treated water collecting tank 620 is provided with a first treated water discharge pipe 621.

The first treatment water discharge pipe 621 is connected to the treatment solution circulation pipe 320 so that the treated water W1 can be recycled as the pressurized water B.

On the other hand, the remaining treated water W1 not discharged to the first treated water discharge pipe 621 in the treated water collecting tank 620 moves to the upper wetting tank 630. The flood tank 630 adjusts the level of the floatation settling tank 200 using the treated water W1.

To this end, a level regulating member 640 is provided at an upper portion of the wet type tank 630. The water level adjusting member 640 is vertically rotatably provided to adjust the maximum height at which the treated water W1 can be received. The level adjusting member 640 is operated by the operating member 660 to adjust its height.

A second treated water discharge pipe 650 is provided below the falling tank 630 to discharge the treated water W1 to the outside.

The operation of the floating separation water treatment system 1 according to the present invention having such a configuration will be described with reference to FIGS. 1 to 8. FIG.

Raw water (not shown) is supplied to the rapid mixing tank 110 of the agitating unit 100 through the raw milk feed inlet 111 as shown in FIGS. The medicine A in the medicine storage tank 113a is supplied to the rapid mixing tank 110 through the medicine supply pipe 113. [ The rapid stirrer 115 of the rapid mixing tank 110 rotates to mix the contaminants contained in the raw water with the chemicals to form coagulated flocs.

The object water W formed with the flocs is supplied to the reaction tank 120 through the side wall 117. In the reaction tank 120, the object water W is stirred by the first full-speed stirrer 121 to grow the flocs. The object water W in the reaction tank 120 is moved to the flocculation tank 130 through the first flow path 125a of the first bank 125 and stirred in the flocculation tank 130 to further grow flocs .

The floated object W to be treated is moved along the second bank 210 and the third bank 220 and flows into the floatation settling tank 200. The processing target water W moved to the third flow path 221 of the third partition 220 is directed to the pressurized water injection nozzle 310 provided at one side of the third flow path 221.

3 and 4, the pressurized water supply passage 316 formed in the pressurized water injection nozzle 310 is formed in the form of a venturi tube, and when the pressurized water B moves, Lt; / RTI > The processing object W having a relatively low pressure is moved to the venturi neck 316a through the inlet hole 312 to be processed of the pressurized water injection nozzle 310 and mixed with the pressurized water B, And is discharged to the hole 317.

In this process, the mixing efficiency with the process target water W and the pressurized water B is improved, and the efficiency of attaching the microbubbles to the flocs can be improved.

 The water W to be treated and the pressurized water B discharged through the pressurized water spray nozzle 310 rise upward along the guide wall 230 and the inclined guide wall 231.

At this time, a plurality of baffles 240 are arranged between the guide wall 230 and the inclined guide wall 231 in the horizontal direction. The baffle 240 delays the moving speed of the process target water W and the pressurized water B to delay the floating speed of the process target water W. In this process, as the contact time between the flocs of the object W to be processed and the minute bubbles of the pressurized water B increases, more flocs contained in the object W to be processed are combined with the micro-bubbles. The floc combined with the micropores forms a scum with a small apparent specific gravity, and the scum floats to the surface of the water.

The scum C is scratched by the scum scraper 450 of the scratch rejection 400 and moved to the scum collection tank 470 side as shown in Fig. The scum scraper 450 is formed by a dual structure of a first scum scraper 451 and a second scum scraper 453 formed horizontally.

As a result, the remaining scum C not scratched by the first scum scraper 451 is scratched by the second scum scraper 453, so that the scum removing efficiency can be raised.

The scum C scraped by the scum scraper 450 falls to the scum collecting tank 470 as shown in Fig. At this time, a plurality of bubble removing mesh nets 471a, 471b, and 471c are provided in the drop path of the scum C, respectively.

The bubble removal mesh nets 471a, 471b, and 471c come into contact with the scum C to break a large amount of bubbles contained in the scum C. When the scum (C) from which the bubbles have been blown is moved from the scum collecting tank (470) to the scum discharge pipe (473) and then subjected to a dehydration process, the dehydration efficiency can be improved.

On the other hand, the sludge (D) accumulated on the bottom of the floatation sedimentation tank 200 which is not floated on the water surface is removed by the sludge removing unit 500. As shown in FIG. 8, the sludge remover 500 is operated such that when the sludge collector chain 530 rotates, the sludge scraper 550 coupled to the sludge collector chain 530 scrapes the sludge D, 560).

The sludge collector driving pulley 510 for driving the sludge collector chain 530 transfers the driving force of the sludge collector driving motor 540 by driving the first magnetic gear 511 and the second magnetic gear 543 Receive. The first magnetic gear 511 and the second magnetic gear 543 are spaced apart from each other with the outer wall of the floatation settling tank 200 therebetween. When the second magnetic gear 543 is rotated by the sludge collector driving motor 540, the second permanent magnets 543a and the first permanent magnets 511a of the first magnetic gear 511 are rotated by the magnetic force And rotates the sludge collector drive pulley 510.

Since the first magnetic gear 511 and the second magnetic gear 543 are not physically directly contacted but transmit the driving force in a state of being separated from the magnetic force, the risk of leakage is reduced as compared with the case where the driving force is transmitted by the conventional physical contact, There is also an advantage of reducing losses.

As described above, the number of objects to be treated W is floated upward from the lower part of the floatation sedimentation tank 200, and the scum C having a small specific gravity is moved to the scratch rejection 400 and then processed. On the other hand, the treated water W1 from which the scum C has been removed flows from the water surface side to the lower side of the floatation sedimentation tank 200 because of relatively large specific gravity and flows into the treated water inflow hole 611 of the treated water collecting pipe 610 .

The treated water W1 that has been transferred to the treated water feeding hole 611 is collected in the treated water collecting tank 620. A part of the treated water W1 in the treated water collecting tank 620 is discharged to the first treated water discharge pipe 621 and then to the processing water through-pipe 320 and then to the pressurized water spraying nozzle 310. [

The remainder of the treated water W1 in the treated water collecting tank 620 is supplied to the mudflow tank 630 and used for adjusting the level of the floatation sedimentation tank 200 and discharged to the outside through the second treated water discharge pipe 650.

As described above, the floatation water treatment apparatus according to the present invention includes a plurality of baffles formed in the horizontal direction on the path of the floatation water at the bottom of the floatation sedimentation tank, thereby delaying the floatation rate of the pressurized water and the treatment object water. In this process, the contact time of the flocs of the object water to be treated and the minute bubbles of the pressurized water is increased, and the flotation efficiency of the flocs contained in the object water can be improved. Thus, the processing efficiency with respect to the number of objects to be treated can be improved.

In addition, the floating separation water treatment apparatus according to the present invention is characterized in that the internal flow path of the pressurized water injection nozzle is formed in the form of a venturi tube, the external target to be treated is sucked into the pressurized water injection nozzle by the high- And then discharged together. This makes it possible to quickly mix the number of objects to be treated and the pressurized water and to mix a large number of objects to be treated with the pressurized water evenly. The possibility of even mixing of the pressurized water and the object water to be treated can lead to an improvement in the treatment efficiency with respect to the object water to be treated.

Meanwhile, in the floatation water treatment system according to the present invention, the scum scraper of the scratch rejection structure is formed in a double structure, and the second scum scraper at the rear is formed longer than the first scum scraper at the front. As a result, the scum that has escaped from the first scum scraper at the front is scratched again by the second scum scraper and is discharged to the outside, so that the scum processing efficiency can be improved.

Further, a plurality of bubble removing mesh nets are provided on the discharge path of the scum, and the bubbles contained in the scum are blown out to the outside. Thus, the dewatering efficiency can be increased in the dewatering process of the scum discharged to the outside.

The floatation water treatment apparatus according to the present invention uses magnetic gears as transmission means for driving a sludge removal unit for removing sludge. The magnetic gears are arranged apart from each other with the floatation settling tank therebetween, and transmit the driving force by the magnetic force of the permanent magnets. Thereby, there is an advantage that the risk of leakage is eliminated and the power loss can be reduced compared with the case where the driving force is transmitted physically.

 It will be apparent to those skilled in the art that various modifications and equivalent arrangements may be made therein without departing from the spirit and scope of the invention as set forth in the appended claims. You will know. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

1: float separation water treatment apparatus 100: stirring part
110: rapid mixing tank 111: raw milk admission
113: medicine supply pipe 113a: medicine storage tank
113b Drug pump 115: Rapid agitator
115a: stirring shaft 115b: stirring paddle
115c: Stirring motor 117: Side wall
120: Reaction tank 121: First slow stirrer
125: first partition 125a: first partition
130: coagulation tank 131: second slow stirrer
200: floating sedimentation tank 210: second partition
211: second flow path 220: third partition
221: third flow path 230: guide wall
231: inclined guide wall 240: baffle
300: pressurized water supply unit 310: pressurized water injection nozzle
311: nozzle body 312: inflow hole
313: upper casing 314: porous partition
315: Target to be treated Feeding 316: Pressurized feeding
316a: Venturi neck 317: Exhaust hole
320: Treatment process outflow pipe 330: Circulation pump
340: air contact tank 350: air compressor
360: Pressurized water supply pipe 370: Pressurized water supply pipe
400: Rejecting combs 410: Scum remover driving pulley
420: scum removing machine, dynamic pulley 430: scum remover chain
440: Scum-fastener 450: Scum scraper
451: first scum scraper 453: second scum scraper
460: Scam remover driving motor 470: Scum collecting tank
471a, 471b, 471c: bubble removal mesh net 472: scum scraper contact block
473: scum drain pipe 500: sludge removing agent
510: sludge collector drive pulley 511: first magnetic gear
511a: first permanent magnet 520: sludge collecting machine dynamic pulley
530: Sludge collector chain 540: Sludge collector drive motor
541: drive shaft 543: second magnetic gear
543a: second permanent magnet 550: sludge scraper
560: sludge collecting tank 600: treated water collecting unit
610: Treated water collecting pipe 611: Treated milk feeding
620: treated water collecting tank 621: first treated water discharge pipe
630: Mooring tank 640: Level control member
650: second process water discharge pipe 660: operating member
A: Drugs
B: Pressurized water
C: Scum
D: Sludge
W: Number to be processed
W1: Processed

Claims (7)

An agitating part (100) for agitating the chemical with the raw water to generate a floc formed water to which contaminants are agglomerated;
A floatation sedimentation tank 200 for separating the water to be treated generated in the agitation unit 100 into floc scum and treated water;
A pressurized water supply unit 300 provided at a lower portion of the floatation settling tank 200 to supply pressurized water containing minute bubbles to float the floc;
A scrubber (400) provided on the floatation settling tank (200) to remove the scum;
A sludge removing unit 500 provided at a lower portion of the floatation settling tank 200 to remove sludge deposited on a bottom surface of the floatation settling tank 200;
And a treated water collecting unit (600) for collecting the treated water separated from the scum in the floatation settling tank (200)
The sludge remover (500)
A sludge collector chain 530 connected to the sludge collector driving pulley 510 and the sludge collecting machine moving pulley 520 spaced apart from each other in the flotation settling tank 200 and rotated in a closed loop form, A sludge collector driving motor 540 for generating a rotating force for rotating the sludge collector driving pulley 510 from the outside of the floatation settling tank 200; ≪ / RTI &
The sludge collector drive pulley 510 is driven by a first magnetic gear 511 and a second magnetic gear 543 disposed so as to be spaced apart from each other by the sludge collector drive motor 540 and the floatation settling tank 200, The first magnetic gear 511 and the second magnetic gear 543 are provided with a plurality of first permanent magnets 511a and a plurality of second permanent magnets 543a arranged in the circumferential direction, And the plurality of first permanent magnets (511a) are alternately arranged with N poles and S poles along the circumferential direction, and the plurality of second permanent magnets (543a) are arranged such that N poles and S poles And the second permanent magnets 543a facing the first permanent magnets 511a are arranged in such a manner that the polarities of the second permanent magnets 543a are opposite to each other, (511) is rotated,
The pressurized water supply unit (300)
A pressurized water circulating pump 330 for supplying the treated water collected in the treated water collecting unit 600 and a pressurized water circulating pump 330 for mixing the treated water supplied by the pressurized water circulating pump 330 with compressed air to form pressurized water An air contact tank 340 and a pressurized water injection nozzle 310 disposed at a lower portion of the floatation settling tank 200 for spraying pressurized water containing fine bubbles into the floatation settling tank 200,
The pressurized water injection nozzle 310 includes a nozzle body 311 connected to the pressurized water supply pipe 360 and formed with a pressurized water supply path 316 into which a pressurized water B flows in the form of a venturi tube, And at least one porous diaphragm (314) arranged to traverse the passage (316)
The water to be treated flows into the pressurized milk feeding path 316 on the outer wall surface of the pressurized water injection nozzle 310 corresponding to the venturi neck 316a having the narrow pressure feeding passage 316, A plurality of target breast-feeding hollows 315 are formed,
The agitation part 100 and the floatation sedimentation tank 200 are partitioned by a third partition 220 having a third flow path 221 formed at a lower part thereof,
The pressurized water injection nozzle 310 is located on the movement path of the water to be treated through the third flow path 221,
A guide wall 230 for guiding a flock floated by fine bubbles ejected from the pressurized water injection nozzle 310 to the water surface is provided on the bottom of the floatation settling tank 200 in which the pressurized water injection nozzle 310 is located, Direction,
The upper end of the guide wall 230 is provided with an inclined guide wall 231 inclined at a predetermined angle so as to gradually increase in width,
The sum rejection (400)
A scum remover chain 430 coupled to the scum remover driving pulley 410 and the scum remover mechanical pulley 420 in a closed loop form and separated from each other at an upper portion of the floatation settling tank 200, And a scum scraper 450 for scraping and moving the scum while the scum is moved together with the same 440. The scum scraper 450 includes a plurality of scum- Including,
The scum scraper 450 is a scum-
The pair of scum is arranged parallel to the east piece 440 at regular intervals,
The second scum scraper 453 positioned rearward with respect to the rotating direction of the pair of scum scraper 450 is longer than the first scum scraper 451 located forward,
The scratch rejecting unit 400 further includes a scum collecting tank 470 disposed at one side of the scum remover driving pulley 410 to collect scum moved by the scum scraper 450,
A scum scraper contact block 472 is formed on the upper part of the scum collecting tank 470. The upper surface of the scum scraper contact block 472 is inclined upwardly along the advancing direction of the scum scraper 450, ), And is formed so as to curve along the rotational curvature of the first-
And a plurality of bubble elimination mesh nets (471a, 471b, 471c) disposed at different heights above the scum collecting tank (470) to discharge bubbles contained in the scum. delete delete delete The method according to claim 1,
A plurality of baffles 240 horizontally disposed at different heights in the direction opposite to each other between the third partition 220 and the guide wall 230 to delay the floating speed of the object water and the minute bubbles, And a water supply pipe connected to the water supply pipe. delete delete

Images