KR101296266B1 - Cooling equipment of wastewater - Google Patents

Abstract

PURPOSE: A wastewater cooling facility is provided to smoothly process an organic wastewater by microorganisms by maintaining a temperature of a bioreactor to generate optimum activity of the microorganisms by using the cooling facility. CONSTITUTION: A wastewater cooling facility comprises a cooling housing (100); a water collecting unit (200); a wastewater scattering unit (300); a scatter cooling unit (400); an air suction unit (500); and a water spray unit (600). Waste water is moved from a bioreactor to the cooling housing. The waste scattering unit scatters the wastewater in a horizontal direction into the water collecting unit. The scatter cooling unit scatters the wastewater falling from the water collecting unit. The air suction unit sucks air outside the cooling housing through an outer slit groove (110) penetrating through an outer wall (120) of the cooling housing in a width direction and an inner slit groove (410) penetrating through a partition plate (420) disposed inside the scatter cooling unit in a depth direction. The water spray unit sprays the water in-flowed from outside of the inner slit groove that is blocked by the wastewater and removes impurities inside the inner slit groove while repeatedly moving up and down along the partition plate.

Description

Wastewater Cooling Facility {COOLING EQUIPMENT OF WASTEWATER}

The present invention relates to a wastewater cooling facility, and more particularly, to a wastewater cooling facility for maintaining an optimal temperature at which microorganisms of wastewater contained in a bioreactor for treating high concentration organic wastewater can be activated.

Due to the continuous industrialization and urbanization, environmental pollution is getting serious day by day, and the shape of discharged sewage, wastewater, and wastewater is also diversified, and the facilities for its treatment are being advanced and treatment costs are increasing.

In addition, as water contaminants in the wastewater that have not been completely treated are introduced into rivers, lakes, and other water sources, there are many problems in efficient water quality management.

Generally, water purification methods such as rivers, dams, and waterways are largely classified into physical purification methods, chemical purification methods, and biological purification methods. Among them, biological purification methods are widely used due to their natural and economic advantages.

Representative methods of biological purification methods include vegetation method, gravel contact oxidation method and biofilm attachment method.

The double vegetation method is to install vegetation in the reservoir / flood water, which has the advantage of good scenery due to natural vegetation and the removal of nitrogen and phosphorus, but requires a large area and requires conditions such as soil for vegetation. However, it is difficult to apply when the lower half (河畔) is made of rock or artificial structure.

In addition, the gravel contact oxidation method can be installed not only in floodplains, reservoirs, but also under the riverbed, and has the advantage that biological and physical treatments occur at the same time, so that it is not affected by sludge, but the treatment efficiency is low and a separate facility site is required for construction. There is a drawback that the sediment is deposited during the installation of the sewerage and the loss of facilities is feared during flooding.

On the other hand, current water and wastewater treatment technologies include physicochemical methods such as sedimentation, pressurized dissolved air flotation (DAF), filtration, chemical coagulation, and oxidation treatment, as well as metabolic processes of microorganisms in bioreactors containing activated sludge. There is a biological treatment method for maximizing and removing various contaminants. The biological treatment method is mainly used for sewage treatment.

In particular, microorganisms may be used to treat high concentration organic wastewater, such as livestock manure wastewater, manure treatment facilities, food wastewater.

In order to treat the high concentration of organic wastewater, the microorganisms are sprayed on the bioreactor to treat the organic wastewater. When the temperature of the bioreactor exceeds 40 ° C, the activation of the microorganisms contained in the bioreactor was significantly reduced.

Therefore, in order to prevent the degradation of the microorganisms, a cooling facility was connected to the bioreactor to cool the bioreactor to be less than 40 ° C.

However, the high concentration of organic wastewater has a problem of clogging the nozzle of the cooling facility due to the high density of the waste water in the course of circulating the cooling facility and the bioreactor.

In addition, the waste water transported from the bioreactor was splashed to the outside of the cooling apparatus in the process of being provided from the upper side to the lower side of the cooling system, or the components were easily damaged by splashing into the components within the cooling system.

Thus, since the density of the high concentration organic wastewater is high, there is a problem that the wastewater is not smoothly treated because the microorganisms of the bioreactor are not activated while the cooling facility is stopped in the course of circulating the cooling facility and the bioreactor.

Patent Document Registration Patent 10-1128679

In order to solve the above problems, the wastewater cooling facility according to the present invention, by cooling the high concentration organic wastewater of the bioreactor through a cooling facility, so that organic wastewater is smoothly processed through the activation of microorganisms contained in the bioreactor. The purpose is to provide a waste water cooling system.

The wastewater cooling system according to the present invention has an object to provide a wastewater cooling system that prevents the nozzles of the cooling system from being blocked by the density of the organic wastewater, so that the performance of the cooling system is maintained so that the organic wastewater can be smoothly treated. have.

Waste water cooling system according to the present invention, the organic waste water circulating in the bioreactor and the cooling facility is prevented from being damaged in the cooling installation as the components of the cooling installation can be minimized to stop the operation of the cooling installation or replace the parts. The purpose is to provide a waste water cooling system.

Waste water cooling facility according to the present invention, the cooling housing 100 is transferred to the waste water 10 is introduced from the bioreactor (50) for treating the organic waste water 10 introduced from the outside using microorganisms; A water collecting part 200 formed at an upper portion of the cooling housing 100 to collect the wastewater 10 flowing into the cooling housing 100; After allowing the wastewater 10 of the bioreactor 50 to be transferred to the cooling housing 100, the wastewater spraying unit 300 spraying the wastewater 10 horizontally inside the water collecting unit 200. ; A partition plate 420 is provided so that at least one compartment is disposed inside the cooling housing 100, and when the wastewater 10 collected in the collecting part 200 falls, the wastewater 10 is scattered. Scattering cooling unit 400; An outer slit groove 110 disposed in parallel with the water collecting part 200 at an upper portion of the cooling housing 100 and penetrating through the outer wall body 120 of the cooling housing 100 in a width direction; Air suction unit 500 for sucking the air outside the cooling housing 100 through the inner slit groove 410 is formed through the partition plate 420 disposed on the inner side of the unit 400 in the width direction ); And spraying water 20 introduced from the outside into the inner slit groove 410 occluded by the waste water 10 while being reciprocated up and down along the partition plate 420 of the inner slit groove 410. It includes; water injection unit 600 for removing the foreign matter.

The water collecting unit 200 has a water collecting tank 210 formed in a box shape having an upper portion opened, and is formed in a plate shape on a lower surface of the water collecting tank 210, and includes a plurality of falling grooves 222 penetrating up and down. And a drop plate 220 to allow the wastewater 10 collected in the water collecting tank 210 to fall while being scattered to the scattering cooling unit 400.

The waste water spraying unit 300, the sprayer 310 for spraying the waste water 10 transferred from the bioreactor 50 to the water collecting unit 200 in the horizontal direction, and the bioreactor 50 in the Flow pipe 320 is connected to the sprayer 310 to form a passage through which the waste water 10 is moved, and the waste water 10 of the bioreactor 50 is connected to the flow pipe 320 is the flow pipe 320 It includes a circulation pump 330 for providing power to the spreader 310 through.

The sprayer 310 sprays the wastewater 10 in a horizontal direction or a horizontal downward direction at a position 2 to 10 cm below the water surface of the wastewater 10 in the water collecting unit 200.

The scattering cooling unit 400, when the wastewater 10 collected in the water collecting unit 200 falls, a plurality of stapled wood veneer layer 430 alternately arranged in a rod form so that the wastewater 10 is scattered. ) And the wood veneer layer 430 formed in a tubular shape at the bottom of the wood veneer layer 430 so that the wastewater 10 cooled while passing through the wood veneer layer 430 may flow into the bioreactor 50. ) And a cooling tube 440 formed to connect the bioreactor 50.

The outer slit groove 110 includes an outer wall curved surface 112 that is curved while being inclined upward in the outward direction of the cooling housing 100, and the inner slit groove 410 is the cooling housing ( It includes a curved surface 412 is inclined upward in the inner direction of 100 is formed.

The air suction unit 500 is disposed above the cooling housing 100 and rotated to allow air outside the cooling housing 100 to pass through the outer slit groove 110 and the inner slit groove 410. And a suction fan 510 suctioning into the cooling housing 100 and a motor 520 connected to an upper portion of the suction fan 510 to provide power to operate the suction fan 510.

The water injection part 600 includes a plurality of injection nozzles 610 for injecting the water 20 into the inner slit groove 410, and a transfer nut 620 fixedly formed to protrude from the injection nozzles 610. And a ball screw which is disposed to face the partition plate 420 vertically and connected to the transfer nut 620 so that the injection nozzle 610 is reciprocated up and down along the partition plate 420. 630 and a sub-motor 640 connected to the ball screw 630 to provide power to the ball screw 630 to rotate in both directions.

The water injection unit 600 is sprayed into the inner slit groove 410, the falling water 20 is discharged from the lower side of the cooling housing 100 to the outside of the cooling housing 100 to the outside. It further comprises a drain pipe 650 in the form of a pipe arrangement.

Wastewater cooling facility according to the present invention, there is a technical effect that the organic wastewater can be smoothly treated by the microorganism by maintaining the temperature of the bioreactor so that the activation of microorganisms through the cooling facility is optimally made.

Waste water cooling system according to the present invention is to prevent the nozzles of the cooling system to blockage, to maintain the performance of the cooling system to smoothly treat the organic waste water to smooth the waste water treatment to improve the work efficiency accordingly There is a technical effect.

The wastewater cooling system according to the present invention has an economical effect that can reduce operating costs because it is possible to prevent the parts of the cooling system from being damaged to minimize the stopping of the cooling system or to replace the parts.

1 is a view showing a wastewater cooling system according to the present invention.
2 is a view showing an embodiment of a wastewater cooling system according to the present invention.
3 is a view showing a main plane of the wastewater cooling system according to the present invention.
4 is a view showing the main portion side in accordance with FIG.
5 is a view showing another main part of the wastewater cooling system according to the present invention.
6 is an enlarged view illustrating main parts of FIG. 6.
7 is a view showing still another main part of the wastewater cooling system according to the present invention.
8 is an enlarged view illustrating main parts of FIG. 7.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views, and length and area, thickness, and the like may be exaggerated for convenience.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

In the following detailed description, for example, the technical configuration of a wastewater cooling system [particularly, a wastewater sprayer, a water sprayer] for maintaining an optimum temperature at which microorganisms of wastewater accommodated in a bioreactor treating high concentration organic wastewater can be activated. Of course, the same can be applied to.

1 is a view showing a wastewater cooling system according to the present invention.

2 is a view showing an embodiment of a wastewater cooling system according to the present invention.

1 and 2, the high concentration organic wastewater 10, such as livestock manure, food wastewater, etc. has a bioreactor 50 for purifying by activating microorganisms in contact with air.

At this time, the microorganisms in the bioreactor 50 may be actively activated, that is, the temperature of the wastewater 10 in which the microorganisms can live is less than 40 ° C.

Therefore, the wastewater 10 can be smoothly decomposed and purified while the microorganisms in the wastewater 10 are activated by using a cooling apparatus so that the temperature of the wastewater 10 can be maintained below 40 ° C. Make sure

In addition, since the concentration of organic wastewater 10 is 7000 to 10000 mg / L, foreign matter may get stuck in the cooling device in the course of being circulated through the cooling device, and thus the cooling device may be broken or the operation may be stopped.

Here, SS (Suspended Solids) is a concentration of suspended solids present in water and is generally suspended particles of 1 μm or more.

In the present invention, while using the cooling device so that the temperature of the wastewater 10 can be maintained at a temperature of less than 40 ℃, it has a configuration that can prevent the cooling device is broken by foreign matters or the operation is stopped.

To this end, in the wastewater cooling facility according to the present invention, the cooling water housing 100 is transported and introduced from the bioreactor 50 for treating organic wastewater 10 introduced from the outside using microorganisms. Has

In addition, the water collecting part 200 is formed on the cooling housing 100 and collects the wastewater 10 introduced into the cooling housing 100.

In addition, after allowing the wastewater 10 of the bioreactor 50 to be transferred to the cooling housing 100, the wastewater spraying unit for spraying the wastewater 10 in the water collecting unit 200 in a horizontal direction ( 300).

In addition, a partition plate 420 is provided so that at least one compartment is disposed inside the cooling housing 100, and when the wastewater 10 collected in the collecting part 200 falls, the wastewater 10 is scattered. It has a scattering cooling unit 400 to be.

The outer slit groove 110 is disposed in parallel with the water collecting part 200 at an upper portion of the cooling housing 100 and penetrates through the outer wall body 120 of the cooling housing 100 in a width direction. Air suction unit for sucking the air outside the cooling housing 100 through the inner slit groove 410 formed in the width direction through the partition plate 420 disposed on the inner side of the scatter cooling unit 400. Has 500.

In addition, the inner slit groove 410 by spraying the water 20 flowing from the outside into the inner slit groove 410 occluded by the waste water 10 while being reciprocated up and down along the partition plate 420. It includes a water injection unit 600 for removing the foreign matter.

Here, the bioreactor 50 is sprayed with microorganisms such as Bacilus Putrificus, and the microorganisms are activated while eating organic materials to treat the wastewater 10.

The microorganisms used in the wastewater 10 are mesophilic microorganisms, and since the optimum temperature for growth is 20 to 40 ° C. and the minimum temperature is less than 15 to 20 ° C., when the temperature of the waste water 10 exceeds 40 ° C., the waste water 10 (10) should be cooled.

Therefore, in order to cool the wastewater 10, the wastewater 10 of the bioreactor 50 is sent to the cooling housing 100, cooled, and then circulated back to the bioreactor 50. .

To this end, the cooling housing 100, the waste water 10 of the bioreactor 50 is introduced into the water collecting unit 200 disposed above the cooling housing 100 to cool the house The support 200 will be supported.

Here, the water collecting unit 200 collects the wastewater 10 introduced from the bioreactor 50 and falls to the scattering cooling unit 400 disposed inside the cooling housing 100. Will be performed.

In addition, the wastewater spraying unit 300 is connected to the bioreactor 50 and the catchment unit 200 so that the wastewater 10 of the bioreactor 50 is transferred to the catcher 200. While providing power, the wastewater 10 performs a function of smoothly collecting water to the water collecting part 200.

On the other hand, the scattering cooling unit 400, partition plate 420 is provided so that one or more compartments are arranged inside the cooling housing 100, the waste water 10 collected in the collecting unit 200 falls At the time, the wastewater 10 serves to scatter.

That is, the scattering cooling unit 400 is to be scattered while the wastewater 10 falling through the collecting unit 200 is more scattered, increase the contact area of the air of the wastewater 10 to the wastewater (10) Heat is lost to the air.

In addition, the air suction part 500 is disposed in parallel with the water collecting part 200 at an upper portion of the cooling housing 100, and directs air outside the cooling housing 100 into the cooling housing 100. Inflow, it is to perform a function to allow the air of normal temperature (15 to 20 ℃) to the waste water 10 of the high temperature (over 40 ℃) falling to the scattering cooling unit 400.

Here, the reason why the air at normal temperature is in contact with the wastewater 10 is to allow the high temperature wastewater 10 to be taken into the air while being in contact with the air at room temperature.

In this case, the cooling housing 100 is formed with a plurality of outer slit grooves 110 formed to penetrate in the width direction on the outer wall body 120 of the cooling housing 100.

In addition, a plurality of inner slit grooves 410 are formed in the partition plate 420 disposed on the inner side of the scatter cooling unit 400 in the width direction.

That is, the air suction unit 500, when the air outside the cooling housing 100 is introduced into the inside, the air outside the cooling housing 100 is the outer slit groove 110 and the inner slit groove. Pass through the 410 sequentially, it can be introduced into the cooling housing 100.

In addition, the water injection unit 600, while reciprocating up and down along the partition plate 420, the water 20 flowing from the outside into the inner slit groove 410 occluded by the waste water (10) By spraying it is performed to remove the foreign matter in the inner slit groove 410.

That is, the inner slit groove 410 may be blocked while the wastewater 10 falling through the collecting unit 200 is scattered sporadically by the scattering cooling unit 400.

At this time, by spraying the water 20 to the inner slit groove 410 occluded through the water spray unit 600 to the foreign material of the waste water 10 generated in the inner slit groove 410 It will be removed.

In addition, the components may be disposed outside the cooling housing 100 to be smoothly controlled from the outside through the controller 70 connected to the devices.

Details of the components will be described in more detail below.

3 is a view showing a main plane of the wastewater cooling system according to the present invention.

4 is a view showing the main portion side in accordance with FIG.

Referring to FIG. 3 and FIG. 4 with reference to FIG. 2, as mentioned above, the water collecting unit 200 collects the wastewater 10 introduced from the bioreactor 50 to the cooling housing 100. ) To fall to the scattering cooling unit 400 disposed in the interior.

To this end, the water collecting part 200 is formed in a collecting tank 210 formed in a box shape having an upper portion and a lower surface of the collecting tank 210 in a plate shape, and a plurality of falling grooves 222 penetrated up and down. ) Is provided to include a falling plate 220 to fall while being scattered to the scattering cooling unit 400 is the wastewater (10) collected in the collection tank (210).

That is, the water collecting tank 210 is a space into which the wastewater 10 introduced from the bioreactor 50 is introduced.

In the present invention, the water collecting tank 210 is disposed above the cooling housing 100, with the air suction unit 500 interposed therebetween, and may be arranged one by one on both sides of the air suction unit 500. .

The drop plate 220 performs a function of allowing the wastewater 10 collected in the water collecting tank 210 to fall while being scattered to the scatter cooling unit 400 through the drop groove 222. Done.

Here, the reason for the fall to the scattered cooling unit 400 through the drop groove 222 is to fall, the air contact area of the waste water 10 to expand the waste water 10 to partially evaporate heat in the air To be taken away.

The falling plate 220 is formed in the shape of a plate while forming the bottom surface of the water collecting tank 210, it is preferable that a plurality of the falling groove 222 is arranged while penetrating the falling plate 220 up and down.

In addition, the drop groove 222 is disposed on the front of the drop plate 220 so that the wastewater 10 entered into the water collecting tank 210 while being aggregated is maximally dispersed to fall to the scattering cooling unit 400. It is formed spaced apart from each other.

In addition, the diameter of the drop groove 222, if the size of the drop groove 222 is not blocked due to the aggregated state of the waste water 10, can be formed in various sizes according to the user's needs. .

On the other hand, as mentioned above, the wastewater spraying unit 300 is connected to the bioreactor 50 and the catchment unit 200 so that the wastewater 10 of the bioreactor 50 is the collection tank ( While providing power to be transferred to 210, the wastewater 10 performs a function of smoothly collecting water to the water collecting part 200.

To this end, the wastewater spraying unit 300 has a sprayer 310 for spraying the wastewater 10 transferred from the bioreactor 50 to the water collecting tank 210 in a horizontal direction.

In addition, the wastewater spraying unit 300 has a flow pipe 320 connected to the spreader 310 in the bioreactor 50 to form a passage through which the wastewater 10 moves.

In addition, the waste water spraying unit 300 is connected to the flow pipe 320 to provide power to the waste water 10 of the bioreactor 50 is transferred to the spreader 310 through the flow pipe 320. It includes a circulation pump 330.

As a result, through the power of the circulation pump 330, the wastewater 10 of the bioreactor 50 is transferred to the interior of the flow pipe 320 and the sparger 310 connected in the water collecting tank 210 ) Is supplied to, and the wastewater 10 is smoothly supplied to the sump tank 210 through the spreader 310.

In particular, the spreader 310 sprays the wastewater 10 in the horizontal direction or horizontally downward position at a position 2 to 10 cm below the water surface of the wastewater 10 in the water collecting tank 210.

Here, the sprayer 310 sprays the wastewater 10 at a position 2 to 10 cm below the water surface of the wastewater 10 in the water collecting tank 210, and the wastewater 10 is collected in the water collecting tank 210. This is because the wastewater 10 having a high concentration of organic matter may be scattered to other parts of the outside or the surroundings of the water collection tank 210 by the drop impact in the process of inflowing to the outside or the surrounding parts.

In addition, the wastewater 10 injection direction of the spreader 310 is preferably sprayed in a horizontal direction or a horizontal downward direction.

The reason is that the sprayer 310 sprays the wastewater 10 horizontally or horizontally in the water collecting tank 210 so that the flocculated suspended matter of the wastewater 10 is lowered in the water collecting tank 210. This is because it is possible to prevent the falling groove 222 of the formed drop plate 220 to be blocked.

That is, due to the spraying pressure of the sprayer 310 spraying the wastewater 10, the flocculated floating matter of the wastewater 10 does not stay in the drop groove 222 and continues to turn in the water collecting tank 210. Because it can be.

5 is a view showing another main part of the wastewater cooling system according to the present invention.

6 is an enlarged view illustrating main parts of FIG. 6.

Referring to FIGS. 2 and 4, referring to FIGS. 5 and 6, as mentioned above, the scatter cooling unit 400 is partitioned so that at least one compartment is disposed inside the cooling housing 100. The plate 420 is provided, and when the wastewater 10 collected in the sump 210 falls, the wastewater 10 is scattered.

That is, the scattering cooling unit 400, so that the waste water 10 falling through the falling groove 222 of the falling plate 220 forming the bottom surface of the water collecting tank 210 is more scattered and scattered, Increasing the contact area of the air of the waste water 10 to induce heat of the waste water 10 to be taken into the air.

To this end, the scattering cooling unit 400, when the waste water 10 collected in the water collecting unit 200 falls, a plurality of stapled staples are arranged in a staggered manner so that the waste water 10 is scattered. Has a layer 430.

In addition, the scattering cooling unit 400 is formed in a tubular shape at the lower portion of the preservative wood layer 430 and the wastewater 10 cooled while passing through the preservative wood layer 430 flows into the bioreactor 50. It further includes a cooling pipe 440 is formed to connect the pre-vacuum layer 430 and the bioreactor 50.

In addition, the scattering cooling unit 400 includes the partition plate 420 and an inner slit groove 410 formed to penetrate through the partition plate 420 in a width direction.

In the present invention, the waterproofing wood layer 430 is disposed one by one in the lower portion of the collecting unit 200 so as to correspond to the collecting unit 200.

That is, the wood veneer layer 430, a pair is disposed facing each other inside the cooling housing 100, it is arranged to be spaced apart from each other while leaving the lower portion of the air intake 500.

Therefore, the preservative wood layer 430 disposed at the lower portion of the water collecting tank 210 disposed on both sides of the air suction unit 500 at the upper portion of the cooling housing 100 is the lower portion of the water collecting tank 210. All of the wastewater 10 that is sporadically dropped into can be introduced into the interior.

In addition, the partition plate 420 is disposed to be spaced apart from each other facing the inside of each of the wood veneer layer 430.

In addition, the inner slit grooves 410 formed in the partition plates 420 disposed to face each other are formed to be inclined upward in the inward direction from the outside of the cooling housing 100.

In addition, each of the inner slit grooves 410 includes a curved surface 412 which is curved while being inclined upwardly from the outside of the cooling housing 100 to the inside thereof.

Similarly, the outer slit groove 110 is formed in the outer wall body 120 of the cooling housing 100 in the width direction.

The outer slit groove 110 includes an outer wall curved surface 112 that is curved while being inclined upward in the outward direction of the cooling housing 100.

At this time, the curved surface 412 of the inner slit groove 410 is formed to be inclined upward from the outer side of the cooling housing 100 inward, and the outer wall curved surface 112 of the outer slit groove 110 is cooled. The reason why the inclined upward in the outer direction of the housing 100 is to prevent the wastewater 10 flows through the inner slit groove 410 and the outer slit groove 110.

That is, between the inner slit grooves 410 formed in the partition plate 420 and the outer slit grooves 110 formed in the outer wall body 120 of the cooling housing 100, the wood veneer layer 430 Is placed.

The wastewater 10 scattered from the wood veneer layer 430 is the space in which the water injection unit 600 is formed through the inner slit groove 410 and the outer slit groove 110, respectively, and the cooling housing 100 The inner slit groove 410 is formed to be inclined upward in the forming direction of the water injection unit 600 in the scattering cooling unit 400, the outer slit groove 110 is By forming the slope wood 430 inclined upward toward the outside of the cooling housing 100, it is possible to minimize the flow of the waste water (10).

In addition, since the inner slit groove 410 has the curved surface 412 having a curved surface, and the outer slit groove 110 has the outer wall curved surface 112 having a curved surface, the wastewater 10 Even if scattered from the wood veneer layer 430 it is difficult to pass through the inner slit groove 410 and the outer slit groove 110 is formed to be inclined upwardly.

As a result, the inner slit groove 410 and the outer slit groove 110 is the waste water 10 scattered from the anti-flood layer 430 is the portion where the water injection unit 600 is formed or the cooling housing 100 By minimizing the flow to the outside of the peripheral parts of the cooling housing 100 is to prevent damage or contamination.

In this way, the inner slit groove 410 and the outer slit groove 110, while the waste water 10 is minimized to flow to the outside of the portion or the cooling housing 100 where the water injection unit 600 is formed It is possible to perform the function of the passage to allow the air outside the cooling housing 100 to enter.

On the other hand, the preservative wood layer 430, when the waste water 10 collected in the sump tank 210 falls through the falling groove 222 of the dropping plate 220, the waste water 10 is hit by the rod to splash. Multiple dogs are stacked and stacked in the form.

Here, the wood veneer layer 430 has a structure in which a plurality dogs are stacked in a staggered manner while being formed in a rod shape.

That is, the preservative wood layer 430 is arranged to be alternately stacked in a rod shape so that the wastewater 10 is dropped from the water collecting tank 210 so as to hit the preservative wood layer 430 and scattered sporadically.

In the present invention, as an example, the wood veneer layer 430 has been described, but the wood veneer layer 430 may be formed of a metal or synthetic resin disposed in a structure similar to the arrangement of the wood veneer layer 430. .

The staggered stack arrangement structure of the wood veneer layer 430, the temperature of the wastewater 10 having a temperature exceeding 40 ℃ collected in the water collection tank 210 and the air at room temperature through the scattering of the wastewater (10) It is a structure for lowering while expanding the contact area.

That is, when the temperature of the wastewater 10 exceeds 40 ℃, the heat of the wastewater 10 is deprived while being in contact with the air of about 15 to 20 ℃, the temperature of room temperature.

At this time, the wastewater 10 is scattered to the scattering cooling unit 400 through the dropping plate 220 while falling, so that the wastewater 10 of the lowest density can be in contact with the air in the widest possible volume. As a result, the air contact area of the wastewater 10 is increased so that heat of the wastewater 10 is taken into the air.

In addition, the air suction part 500 is disposed parallel to the water collecting part 200 at an upper portion of the cooling housing 100, and is formed to penetrate through the outer wall body 120 of the cooling housing 100 in the width direction. Outside the cooling housing 100 through the outer slit groove 110 and the inner slit groove 410 formed in the width direction through the partition plate 420 disposed on the inner side of the scattering cooling unit 400 in the width direction. Inhale air into the interior.

That is, the air suction part 500 is disposed in parallel with the water collecting part 200 at an upper portion of the cooling housing 100, and directs air outside the cooling housing 100 into the cooling housing 100. Inflow, it is to perform a function to allow the air of normal temperature (15 to 20 ℃) to the waste water 10 of the high temperature (over 40 ℃) falling to the scattering cooling unit 400.

To this end, the air suction unit 500 is disposed on the upper portion of the cooling housing 100 and rotated so that the outside slit groove 110 and the inner slit groove 410 allow air outside the cooling housing 100 to rotate. It has a suction fan 510 to suck into the cooling housing 100 through.

In addition, the air suction unit 500 includes a motor 520 connected to an upper portion of the suction fan 510 to provide power to operate the suction fan 510.

That is, the suction fan 510 is rotated by receiving power from the motor 520 to introduce the air from the outside of the cooling housing 100 into the inside.

As a result, the preservative wood layer 430 of the scattering cooling unit 400, when the wastewater 10 collected in the sump tank 210 falls through the falling groove 222 of the falling plate 220, The waste water (10) is to hit and splash.

In addition, the suction fan 520 of the air suction unit 500 may be in contact with the room temperature air introduced from the outside of the cooling housing 100 to the waste water 10 scattered from the preservative wood layer 430. To ensure that

As a result, the temperature of the wastewater 10, which has exceeded 40 ° C, may be cooled to be close to the temperature of room temperature.

7 is a view showing still another main part of the wastewater cooling system according to the present invention.

8 is an enlarged view illustrating main parts of FIG. 7.

Referring to FIG. 2, referring to FIGS. 7 and 8, as mentioned above, the water spray unit 600 is reciprocated up and down along the partition plate 420, by the wastewater 10. By spraying the water 20 introduced from the outside into the closed inner slit groove 410 to perform the function of removing the foreign matter of the inner slit groove 410.

The inner slit groove 410 is occluded while the wastewater 10 falling through the drop groove 222 of the drop plate 220 from the water collecting tank 210 is scattered sporadically by colliding with the anti-flouring layer 430. Can be.

At this time, by spraying the water 20 to the inner slit groove 410 occluded through the water spray unit 600 to the foreign material of the waste water 10 generated in the inner slit groove 410 It will be removed.

Here, the water spray unit 600, one or more may be formed in the cooling housing 100, in the present invention may be disposed between the partition plate 420, a pair is disposed facing each other. .

To this end, the water injection unit 600, a plurality of injection nozzles 610 for injecting the water 20 to the inner slit groove 410 and the transfer is fixed to protrude to the injection nozzle 610 Has a nut 620.

In addition, the water injection unit 600 is disposed vertically facing the partition plate 420 and connected to the transfer nut 620 so that the injection nozzle 610 is vertically along the partition plate 420. It has a ball screw 630 that is bidirectionally rotated to reciprocate.

The water injection unit 600 includes a sub-motor 640 connected to the ball screw 630 to provide power to the ball screw 630 to rotate in both directions.

The water injection unit 600 is sprayed into the inner slit groove 410, the falling water 20 is discharged from the lower side of the cooling housing 100 to the outside of the cooling housing 100 to the outside. It further comprises a drain pipe 650 in the form of a pipe arrangement.

The spray nozzle 610 is connected to a water supply pipe 660 to allow the water 20 to flow into the spray nozzle 610 from the outside of the cooling housing 100.

Here, the water supply pipe 660 is made of a flexible synthetic resin when the injection nozzle 610 is raised or lowered on the ball screw 630, so as not to interfere with the lifting and lowering operation.

Since a plurality of the inner slit grooves 410 are disposed along the wall surface of the partition plate 420, the injection nozzle 610 repeatedly moves up and down along the wall surface of the partition plate 420. While reciprocating to, the water 20 is sprayed into the inner slit groove 410 to remove foreign substances generated in the inner slit groove 410 occluded by the waste water 10.

Here, the water 20 supplied to the injection nozzle 610 through the water supply pipe 660 is injected into the inner slit groove 410 through the injection nozzle 610, the inner slit groove By spraying the water 20 on the 410, the foreign matter generated in the inner slit groove 410 can be smoothly removed.

The transfer nut 620 is raised or lowered along the ball screw 630 by the rotation of the ball screw 630.

That is, when the ball screw 630 is rotated in one direction, the transfer nut 620 is elevated, and when the ball screw 630 is rotated in the opposite direction, the transfer nut 620 Is going to descend.

In this case, since the injection nozzle 610 is fixedly formed on the transfer nut 620, the injection nozzle 610 may be raised or lowered according to the flow of the transfer nut 620, and the water 20 may be moved to the inner side. It is injected into the slit groove 410.

In addition, the sub-motor 640 provides the power to rotate the ball screw 630 in one direction and the opposite direction.

Finally, the drain pipe 650, when the water 20 injected into the inner slit groove 410 through the injection nozzle 610 falls to the lower portion of the cooling housing 100, the drain pipe 650 After the flow into the) to perform the function of the passage to be discharged to the outside of the cooling housing (100).

To this end, a lower bottom surface of the cooling housing 100 in which the drain pipe 650 is disposed may be inclined downward in the direction in which the drain pipe 650 is formed.

As a result, by removing the foreign matter generated in the inner slit groove 410 through the water spraying unit 600, the air suction unit 500 draws air outside the cooling housing 100 to the outer slit groove ( Through the 110 and the inner slit groove 410 will be able to smoothly flow into the cooling housing 100.

Through this configuration, it is possible to obtain a technical effect that the organic waste water can be smoothly treated by the microorganisms by maintaining the temperature of the bioreactor so that the activation of the microorganisms through the cooling facility is optimally made.

In addition, the nozzle of the cooling system is prevented from being blocked, so that the performance of the cooling system is maintained so that the organic wastewater can be smoothly treated, so that the wastewater can be smoothly treated, thereby obtaining a technical effect of improving work efficiency. .

In addition, since the parts of the cooling system can be prevented from being damaged, the operation of the cooling system can be minimized or the replacement of the parts can be minimized, thereby reducing the operating cost.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

10: wastewater 20: water
50: bioreactor
100: cooling housing 110: outer slit groove
112: outer wall curved surface 120: outer wall
200: water collecting unit 210: water collecting tank
220: falling plate 222: falling groove
300: waste water spraying unit 310: sprayer
320: flow pipe 330: circulation pump
400: scattering cooling unit 410: inner slit groove
412: curved surface 420: partition plate
430: wood preservation layer 440: cooling tube
500: air suction unit 510: suction fan
520: motor
600: water injection unit 610: spray nozzle
620: Feed Nut 630: Ball Screw
640: sub-motor 650: drain pipe

Claims (9)

Cooling housing 100 is transported and introduced from the biological reaction tank 50 for treating the organic wastewater 10 introduced from the outside using a microorganism;
A water collecting part 200 formed at an upper portion of the cooling housing 100 to collect the wastewater 10 flowing into the cooling housing 100;
After allowing the wastewater 10 of the bioreactor 50 to be transferred to the cooling housing 100, the wastewater spraying unit 300 spraying the wastewater 10 horizontally inside the water collecting unit 200. ;
A partition plate 420 is provided so that at least one compartment is disposed inside the cooling housing 100, and when the wastewater 10 collected in the collecting part 200 falls, the wastewater 10 is scattered. Scattering cooling unit 400;
An outer slit groove 110 disposed in parallel with the water collecting part 200 at an upper portion of the cooling housing 100 and penetrating through the outer wall body 120 of the cooling housing 100 in a width direction; Air suction unit 500 for sucking the air outside the cooling housing 100 through the inner slit groove 410 is formed through the partition plate 420 disposed on the inner side of the unit 400 in the width direction ); And
Reciprocating up and down along the partition plate 420, the foreign matter of the inner slit groove 410 by spraying the water 20 introduced from the outside into the inner slit groove 410 occluded by the waste water 10 Waste water cooling facility comprising a; water spraying unit 600 to remove. The method of claim 1,
The water collecting unit 200,
A water collecting tank 210 formed in a box shape having an upper portion opened,
The waste water tank 10 is formed in a plate shape on a lower surface of the water collecting tank 210, and is provided with a plurality of drop grooves 222 penetrating up and down, and the wastewater 10 collected in the water collecting tank 210 is transferred to the scattering cooling unit 400. Wastewater cooling facility comprising a dropping plate 220 to fall while falling.
The method of claim 1,
The waste water spraying unit 300,
A sprinkler 310 for spraying the waste water 10 transferred from the bioreactor 50 to the water collecting part 200 in a horizontal direction;
A flow pipe 320 connected to the spreader 310 in the bioreactor 50 to form a passage through which the wastewater 10 moves;
Wastewater cooling connected to the flow pipe 320 includes a circulation pump 330 for providing power to the waste water 10 of the bioreactor 50 is transferred to the spreader 310 through the flow pipe 320 equipment.

The method of claim 3, wherein
The spreader 310,
Waste water cooling facility characterized in that to spray the waste water (10) in the horizontal direction or horizontal down direction at a position 2 to 10 cm below the water surface of the waste water (10) inside the water collecting unit (200).
The method of claim 1,
The scattering cooling unit 400,
When the wastewater 10 collected in the water collecting unit 200 falls, the wastewater layer 430 is arranged in a staggered manner in a plurality of rods so that the wastewater 10 is scattered while flying,
It is formed in a tubular shape in the lower portion of the wood veneer layer 430 is passed through the wood veneer layer 430 so that the cooling water 10 is introduced into the bioreactor 50, the wood veneer layer 430 and the Waste water cooling facility further comprises a cooling pipe 440 is formed to connect the bioreactor (50).
The method of claim 1,
The outer slit groove 110,
It includes an outer wall curved surface 112 is curved inclined upward in the outer direction in the cooling housing 100,
The inner slit groove 410,
Waste water cooling facility comprising a curved surface 412 is curved inclined upward in the inward direction in the cooling housing (100).
The method of claim 1,
The air suction unit 500,
It is disposed on the upper portion of the cooling housing 100 and rotated to suck air outside the cooling housing 100 into the cooling housing 100 through the outer slit groove 110 and the inner slit groove 410. Suction fan 510,
Waste water cooling facility comprising a motor (520) connected to the upper portion of the suction fan (510) for providing power to operate the suction fan (510).
The method of claim 1,
The water injection unit 600,
A plurality of spray nozzles 610 for spraying the water 20 into the inner slit grooves 410,
A transfer nut 620 fixedly formed to protrude from the injection nozzle 610;
The ball screw 630 is connected to the transfer nut 620 while being disposed vertically facing the partition plate 420 and rotated in both directions so that the injection nozzle 610 is reciprocated up and down along the partition plate 420. ,
Waste water cooling facility comprising a sub-motor (640) connected to the ball screw (630) for providing power to the ball screw (630) to rotate in both directions.
The method of claim 8,
The water injection unit 600,
The water pipe 650 which is connected to the outside from the lower portion of the cooling housing 100 so that the water 20 is dropped into the inner slit groove 410 and then discharged to the outside of the cooling housing 100. Wastewater cooling system further comprising).

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