KR200399489Y1 - A waste water disposal plant with advanced ozone oxidationn - Google Patents

Abstract

The improved ozone oxidation type wastewater treatment device that strengthens the pretreatment process according to the present invention has a screen tank 12 for preventing unnecessary rainwater mixing by an inflow shutoff valve 11 exposed to all stages of wastewater flowing into the collection tank 10. The inside of the screen tank 12 is installed an activated carbon fiber double screen 16 to adsorb the chemicals contained in the car wash water in large quantities and to perform a pretreatment process to filter foreign substances such as impurities. There is an effect of improving the facility margin and pollutant removal rate according to the pollutant load reduction effect in the rear end equipment.

In addition, the ozone oxidation tank 20 according to the present invention is provided with a swirl flow multi-contact device 22 to form a swirling vortex therein to increase the residence period of the fluid, the swirl flow multi-contact device 22 By providing the reducing venturi tube 25 for increasing the speed of the fluid flowing into the fluid inlet (24a), there is an effect to significantly improve the ozone contact efficiency compared to the conventional ozone contact tank.

In addition, the microbubble-type ceramic spraying device 40 is provided in the pressurized floatation tank 30 according to the present invention, and the ozone contact is caused by colliding microbubbles with colloidal aggregates generated by oxidative decomposition in the ozone oxidation tank 20. There is another effect of increasing efficiency.

Description

A waste water disposal plant with advanced ozone oxidationn

The present invention relates to a wastewater treatment device for easily collecting and separating contaminants by ozone oxidation without using chemicals, detergents, oil particles, and scum contained in general wastewater. In the previous stage, a screen tank is installed to block unnecessary rainwater mixing by the exposure type inlet shutoff valve, and an activated carbon fiber double screen is installed inside the screen tank to adsorb chemical substances contained in the car wash waste water. At the same time, the present invention relates to an improved ozone oxidation wastewater treatment system that has enhanced the pretreatment process to improve the facility margin and contaminant removal rate according to the effect of reducing pollutant load in the downstream equipment by performing the pretreatment process to filter foreign substances such as contaminants.

In addition, in order to improve the high ozone generation and contact efficiency, an ozone oxidation tank equipped with a swirling nozzle using a reducing venturi tube and a swirling flow multi-contact device for forming a vortex is installed and oxidatively decomposed in the ozone oxidation tank. The present invention relates to an improved ozone oxidation wastewater treatment system that has enhanced the pretreatment process to efficiently remove the colloidal aggregates generated through the microbubble-type ceramic spraying device of the pressurized flotation tank.

In general, the most important point in a device or method for separating and removing detergents, oil particles or debris contained in waste water is to treat the oil particle characteristics and the degree of mixing of the suspension.

At this time, when looking at the shape of the oil particles contained in the waste water, when the diameter of the oil particles is 150㎛ or more free oil, and when the diameter of the oil particles 60㎛ or less emulsion oil (Emulsion Oil) and certain particles It is divided into oil-attached oil that is attached to the oil.

On the other hand, looking at the apparatus for treating according to the size of the oil particles, it is divided into a simple gravity-separated oil-water separator for separating the free oil and a pressure flotation separator for treating emulsion oil and adhesive oil.

However, the conventional wastewater treatment apparatus has no means for preventing rainwater from being mixed in the rainwater collection tank, and a large amount of rainwater flows during heavy rains, causing serious problems in facility overload operation and facility durability.

In addition, the contaminated water flowing into the sump tank is generally stored after removing only the sedimentary solids, and this contaminated water causes a load on the post treatment facility.

On the other hand, the conventional wastewater treatment apparatus has to transfer ozone from the ozone generator to the contact facility through the pipe in order to contact the wastewater with ozone, but in this case, the ozone efficiency decreases due to the loss of ozone and the reaction of the generated oxygen. Therefore, it causes the power loss and maintenance cost to be increased in the ozone generator.

In addition, by using the ozone oxidizing power by contacting the wastewater introduced into the improved ozone contactor with water, the pollutants (surfactants, bacteria, odorous substances, color, BOD, etc.) contained in the wastewater can be discharged using oxygen from the ozone generator. Oxidative decomposition is caused, but the efficiency is not constant according to the contactor size (volume) and the contact method (diaphragm, partition), and an unreacted ozone is generated, causing a problem of acting as a pollutant in the surroundings.

The present invention has been devised to solve the above problems, the screen tank is installed in the previous stage of the waste water flow into the collecting tank to block unnecessary rainwater mixing by the exposure type inlet shut-off valve, the inside of the screen tank By installing activated carbon fiber double screen, pretreatment process that absorbs the chemicals contained in car wash waste water and filter out foreign substances such as contaminants is carried out. The purpose of the present invention is to provide an improved ozonation type wastewater treatment system that has enhanced the pretreatment process.

In addition, in order to improve the high ozone generation and contact efficiency, an ozone oxidation tank equipped with a swirling nozzle using a reducing venturi tube and a swirling flow multi-contact device for forming a vortex is installed and oxidatively decomposed in the ozone oxidation tank. It is another object of the present invention to provide an improved ozone oxidation wastewater treatment system that has enhanced the pretreatment process for efficiently removing the colloidal aggregates generated through the microbubble-type ceramic spraying device of the pressurized flotation tank.

The improved ozone contact type pressurized wastewater treatment device for strengthening the pretreatment process according to the present invention for achieving the above object, the exposure type inlet shutoff valve and activated carbon on the inlet side of the collection tank provided in the conventional ozone oxidation wastewater treatment device A screen tank equipped with a double screen is added to reinforce the pretreatment process of waste water, and the ozone oxidation tank equipped with a reducing venturi tube and a swirl flow multi-contact device is used to oxidize and decompose foreign matter into colloidal aggregates. It is a technical feature to efficiently remove the colloidal aggregates through the microbubble type ceramic spraying device of the pressure floating tank.

Hereinafter, with reference to the accompanying drawings, an embodiment of an improved ozone oxidation wastewater treatment system to enhance the pretreatment process according to the present invention is as follows.

1 is a process diagram schematically showing a wastewater treatment apparatus according to the present invention, Figure 2 is a cross-sectional view showing a screen tank of Figure 1, Figure 3 is a cross-sectional view showing a swirl flow multi-contact device of Figure 1, Figure 4 The perspective view which showed the pressurization float tank of 1.

As shown in FIG. 1, the wastewater treatment apparatus according to the present invention includes a collecting tank 10, an ozone oxidation tank 20, a pressure flotation tank 30, a pressure filter 50, a sludge collector 60, and It includes a treated water tank (70).

When the waste water to be treated is stored in the collection tank 10 and a waste water treatment operation is carried out, the wastewater treatment operation is transferred to the ozone oxidation tank 20. In the present invention, the previous stage of the collection tank 10 to strengthen the pretreatment process. In the separate screen tank 11 is installed.

The waste water inlet side of the screen tank 11 is provided with an exposure type flow cutoff valve 12 to block rainwater from being directly introduced when the rain process is performed.

This is to prevent the wastewater treatment apparatus from leaving the initial set-up state due to excessively introduced rainwater or the like and causing a process error.

On the other hand, the influent wastewater contains a large amount of surfactants, and since the influent water quality is not constant due to the characteristics of generation, it adversely affects the water quality of the treated water, and thus, the carbon filter 13 as a filtration means inside the screen tank 12. On both sides of the screen 14 is provided with an activated carbon fiber double screen 16 coupled, the activated carbon fiber double screen 16 is obliquely to the bottom surface of the screen tank 12 by a bracket (15) Is installed.

The activated carbon fiber double screen 16 adsorbs ABS (anionic surfactant) and nH (normal hexane) contained in the influent wastewater using the carbon filter 13, and filters foreign substances such as impurities from the screen 14. Given. As a result, in the downstream equipment, the load due to the treatment of pollutants is reduced, and the equipment margin is increased, and the pollutant removal rate is also doubled.

At this time, the activated carbon fiber double screen 16 is installed to be detachable to the bracket 15, it can be easily washed and reused after a certain time.

On the other hand, the ozone oxidation tank 20 is a wastewater flows from the collection tank 10 connected to the wastewater inflow line (L1) to treat the contaminants contained in the wastewater by ozone oxidation technology, ozone decomposition oxygen and a hydroxyl group (OH ^-) occurs when as by using the principles of organic matter is oxidized and decomposed, and the ozone generator 21 is connected to the ozone inlet line (L2).

Since the ozone generator 21 is a conventional known technology, a detailed description thereof will be omitted below.

In the present invention, in order to increase the ozone contact efficiency of the ozone oxidation tank 20, as shown in FIG. 3, a swirl flow multi-contact device 23 is formed to form a vortex therein.

The swirl flow multi-contact device 22 is composed of a cylindrical body installed perpendicular to the fluid supply pipe 23, the reducing venturi tube 25 is connected to the fluid inlet (24a) connected to the fluid supply pipe (23) ) Is provided to improve the flow rate of the fluid.

At this time, a separate fluid suction port 24b is formed on the bottom surface, and a circulation action is performed in which fluid passing through the swirl flow multiple contact device 22 is sucked again.

In addition, a swirl flow forming plate 26 is formed inside the swirl flow multi-contact device 22 to form swirl flow in the waste water, and a fluid crushing protrusion 27 for finely crushing the sucked fluid is provided on the upper side thereof. A fluid flow guide vane 28 is provided to guide the flow of the fluid.

Therefore, the fluid of the fluid supply pipe 23 is rapidly introduced into the fluid inlet 24a by the reducing venturi tube 25 and guided in a predetermined direction by the swirl flow-forming plate 26 to move upward. At this time, the fluid is crushed and crushed by the fluid crushing projection 27, swirled by the fluid flow guide blades 28, the residence period is increased and discharged to the outside of the swirl flow multi-contact device 22.

At this time, the discharged fluid is again sucked into the fluid suction port 24b to cause the same circulation action and form a vortex to continuously contact with ozone.

Therefore, the swirl flow multi-contact device 22 maximizes the contact of the waste water and ozone by the conventional ozone oxidation tank to improve oxidative decomposition and at the same time significantly reduce the ozone, each component systematically The size is also compact.

On the other hand, the pressurized floatation tank 30 according to the present invention is connected to the ozone water inlet line (L3) on one side as shown in Figures 1 and 4, the oil particles floating by adsorption and floating by the micro-bubbles in the central portion Contaminant discharge line (L4) for discharging the contaminant including is connected, the microbubble spray line (L7) for supplying the microbubble and the filter connecting line (L5) is connected to the lower side.

At this time, the microbubble-type ceramic spraying device 40 is installed at the bottom of the inlet side of the pressurized floatation tank 30 to float a large amount of microbubbles upwards so that the contaminants rise together with the microbubbles.

That is, the microbubble-type ceramic spraying device 40 forms microbubbles by colliding external air introduced into the ejector 72 with the ceramic baffle plate, thereby increasing the residence time of the microbubbles in the water, and thus, in the pressurized floatation tank 30. In order to efficiently remove the bubbles of the surfactant in the, and when a large number of micro bubbles are generated due to the pressure-reducing effect of the dissolved air introduced into the pressure floating tank (30), the micro bubbles adsorb the oil particles and then oil particles It has the function of removing by floating.

In this case, the ceramic baffle plate is a plate of a ceramic member having a plurality of fine air holes (200 to 400 μm) formed in an upper layer, and external air introduced at a predetermined pressure or more from the ejector 72 collides with the baffle plate, Micro bubbles are released through the air holes.

In addition, the upper portion of the pressurized floatation tank 30 is combined with a scattering prevention cover 31 for preventing the odor of pollutants and the scattering of bubbles that may occur during oxidative decomposition.

Meanwhile, as shown in FIGS. 2 and 3, one side of the pressure injury tank 30 stores oil and sludge separated and removed from the pressure injury tank 40, and has a function of naturally dehydrating and drying the same. The sludge collector 60 is provided.

The pressure filter 50 sifts contaminants, such as COD, suspended solids, normal hexane (n-Hexan), ABS, etc., in the wastewater supplied from the pressurized floatation tank 30 to the filter connecting line L5. As the final treatment using the adsorption function, the final treated water is collected into the treated water tank 70 and the filtration unit 52 inside the pressure filter 50 is configured to perform automatic cleaning according to the operating time.

That is, the pressure filter 50 is connected to the treated water tank 70 and the backwashing line L6 and is automatically cleaned by the filtered water supplied to the backwashing line L6 through a predetermined state or any manipulation. You lose.

The treated water tank 70 serves to store the filtered water discharged from the pressurized floatation tank 30 and filtered in the pressure filter 50, and the filtered water is a pressurized water and a pressure filter 50 required by the apparatus. It is used as the washing water for washing the filtration unit 52 of the). On the other hand, the microbubble spray line (L7) connecting the pressurized floatation tank (30) from the treated water tank (70) is provided with a cleaning pump (71) and an ejector (72) to pressurize and supply the mixed air and the washing water. .

Referring to the progress of the wastewater treatment device configured as described above are as follows.

First, the wastewater to be treated is stored in a predetermined amount in the collection tank 10 after the pretreatment process is performed in the screen tank 12, and when the wastewater is supplied to the improved ozone contactor 20, ozone supplied from the ozone generator 30 And contaminants in the wastewater react and are first oxidized.

At this time, it is possible to control by the state of the rear end equipment as well as blocking the rain to be introduced into the screen tank (11) and the collection tank (10) in rainy weather by the exposure type flow shutoff valve (12) in advance.

In addition, the screen tank 12 blocks the contaminants, sedimentary solids and suspended solids from the contaminants introduced into the collection tank 10 and adsorbs the normal hexane component and the surfactant component generated during the washing process. Helps improve efficiency, contributes to durability.

Subsequently, the swirl flow is generated by the swirl flow multi-contact device 22 installed below the ozone oxidation tank 20 to minimize unreacted ozone through continuous fluid suction, and the waste water is ozone oxidation tank 20. Sprayed to the top of) to induce a secondary reaction to allow complete oxidation of the waste water.

Next, when the waste water oxidized by ozone is supplied to the pressurized floatation tank 30 through the ozone water inflow line L3, by the cleaning pump 71 and the ejector 72 provided in the microbubble injection line L7. The air and the filtered water are pressurized and supplied, and the pressurized air and the filtered water collide with each other in the microbubble type ceramic spraying device 40 to form microbubbles. This microbubble contacts the remaining wastewater and separates oil particles remaining in the remaining wastewater.

At this time, the scattering prevention cover 31 effectively prevents scattering due to excessive generation of odor and bubbles that may occur during oxidative decomposition, and keeps the indoor environment of the treatment facility clean.

The treated water undergoes a series of processes by completely removing the deodorizing component and the colloidal component from the pressure filter 50 through sieving, precipitation collision, blocking, and physicochemical adsorption effects.

The improved ozone oxidation type wastewater treatment device that strengthens the pretreatment process according to the present invention has a screen tank 12 for preventing unnecessary rainwater mixing by an inflow shutoff valve 11 exposed to all stages of wastewater flowing into the collection tank 10. The inside of the screen tank 12 is installed an activated carbon fiber double screen 16 to adsorb the chemicals contained in the car wash water in large quantities and to perform a pretreatment process to filter foreign substances such as impurities. There is an effect of improving the facility margin and pollutant removal rate according to the pollutant load reduction effect in the rear end equipment.

In addition, the ozone oxidation tank 20 according to the present invention is provided with a swirl flow multi-contact device 22 to form a swirling vortex therein to increase the residence period of the fluid, the swirl flow multi-contact device 22 By providing the reducing venturi tube 25 for increasing the speed of the fluid flowing into the fluid inlet (24a), there is an effect to significantly improve the ozone contact efficiency compared to the conventional ozone contact tank.

In addition, the microbubble-type ceramic spraying device 40 is provided inside the pressurized floatation tank 30 to increase ozone contact efficiency by colliding microbubbles with colloidal aggregates generated by oxidative decomposition in the ozone oxidation tank 20. It has a different effect.

1 is a process diagram schematically showing a wastewater treatment apparatus according to the present invention,

2 is a cross-sectional view showing the screen tank of FIG.

3 is a cross-sectional view showing the swirl flow multi-contact device of FIG.

Figure 4 is a perspective view of the pressure floating tank of Figure 1;

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

10: collecting tank 11: screen tank

12: Exposure type inlet shutoff valve 13: Carbon filter

14: Screen 15: Bracket

16: activated carbon fiber double screen

20: ozone oxidation tank 21: ozone generator

22: swirl flow multi-contact device 23: fluid supply pipe

24a: fluid inlet 24b: fluid inlet

25: reducing venturi tube 26: swirl flow forming plate

27: fluid fracture protrusion 28: fluid flow guide wings

30: pressure floating tank 31: shatterproof cover

40: micro bubble ceramic spray device 50: pressure filter

60: sludge collector 70: treated water tank

71: cleaning pump 72: ejector

Claims (6)

In the wastewater treatment apparatus using ozone comprising a collecting tank, ozone generator, ozone oxidation tank, pressurized flotation tank, pressure filter, sludge collector and treated water tank, A screen tank installed at all stages of the collection tank and integrally including a filtering means consisting of a flow blocking valve and an activated carbon fiber double screen to block unnecessary rainwater mixing; An ozone oxidation tank for forming a vortex through the swirl flow multi-contact device to increase the contact between the ozone supplied from the ozone generator and the waste water supplied from the collecting tank; An improved ozonation-type wastewater treatment apparatus for strengthening the pretreatment process, comprising a pressurized floatation tank integrally containing a microbubble-type ceramic spraying unit for microbubbling the dissolved air supplied by the eject. The method of claim 1, The activated carbon fiber double screen is an improved ozone oxidation wastewater treatment system for strengthening the pretreatment process, characterized in that the screen is coupled to both sides of the carbon filter in the center, the bracket is installed obliquely on the bottom surface of the screen tank. The method of claim 1, The swirl flow multi-contact device is installed perpendicular to the fluid supply pipe, A fluid inlet port through which the fluid of the fluid supply pipe is introduced; A swirl flow forming plate provided above the fluid inlet to form swirl flow in the waste water; A fluid crushing protrusion provided on an upper side of the swirl flow forming plate to crush the sucked fluid; A fluid flow guide vane for inducing a flow of fluid crushed by the fluid crushing protrusion; An improved ozone oxidation type wastewater treatment apparatus for strengthening a pretreatment process, characterized in that it includes a fluid inlet for sucking back the fluid discharged to the outside. The method of claim 3, wherein The fluid inlet is an improved ozone oxidation wastewater treatment system to enhance the pretreatment process, characterized in that the inlet portion is formed as a reducing venturi tube to increase the flow rate of the fluid. The method of claim 1, The microbubble-type ceramic spraying device is a pretreatment characterized by generating external air supplied from the ejector by colliding with a ceramic baffle plate having a plurality of air holes having a pore diameter of 200 to 400 μm thereon. Improved ozone oxidation wastewater treatment system with enhanced process. The method of claim 1, An improved ozone oxidation wastewater treatment system for enhancing the pretreatment process, characterized in that the scattering prevention cover is coupled to the upper side of the pressurized floatation tank.