KR100908866B1 - Recirculating ozone water treatment device and recirculating ozone water treatment method using the same - Google Patents

Abstract

The present invention relates to a recirculating ozone water treatment apparatus, comprising: a raw water tank into which raw water is introduced or discharged; An ozone supplier for supplying ozone gas to the raw water introduced from the raw water tank; A complex reactor for homogeneously mixing the raw water supplied with the ozone gas so as to reduce the amount of dissolved ozone in the raw water by promoting the oxidation reaction of the ozone gas, and turbulizing the flow to generate ozonated water; And an ozone treatment tank into which the ozone treatment water flows in or out, wherein the raw water tank and the ozone treatment tank communicate with each other, such that the oxidation reaction of the ozone gas remaining in the ozone treatment water is highly contaminated by the raw water. A portion of the ozonated water of the ozone treatment tank is mixed with the raw water of the raw water tank and recycled so as to be promoted due to the concentration.

By using the recirculating ozone water treatment apparatus of the present invention, high concentration waste water and waste water can be purified in a short time with a small amount of ozone, and ozone utilization efficiency can be increased, thereby reducing the cost of water treatment. In addition, it is possible to easily purify difficult-decomposable substances that are difficult to purify by the conventional ozone treatment technology, and can be implemented in a small size compared to the treatment capacity.

Water treatment device, waste water treatment device, ozone treatment tank, ozone, recirculation type

Description

Recirculating ozone water treatment apparatus and recirculating ozone water treatment method using the same {water treatment apparatus of recirculation type with ozone gas and water treatment method of recirculation type with ozone gas using the same}

The present invention relates to a recirculating ozone water treatment device, and more particularly, to a recirculating ozone water treatment device capable of purifying a high concentration of wastewater with a small amount of ozone in a short time.

Water treatment method using ozone is widely used in various water treatment fields such as advanced water treatment, wastewater treatment, and leachate treatment, such as treating organic substances and sterilizing pathogenic microorganisms with strong oxidizing and sterilizing power of ozone.

The ozone water treatment apparatus using the ozone water treatment method has a variety of types of raw water to be treated, can be easily installed and maintained at a relatively low cost, as well as the water treatment effect is more widely used.

Such ozone water treatment methods include an acid generator method, an injector method, a pressure pump method, and a turbine mixer method. However, in the treatment of high concentration wastewater, an acid gas method capable of supplying a large amount of ozone by diffusing ozone gas into fine bubbles through a diffuser is mainly used. In other ozone water treatment methods, a lot of energy is consumed to operate the device, and the removal rate of pollutants is relatively low compared to energy consumption.

The conventional ozone water treatment apparatus using the above-described acidic method is designed to deeply design the acid depth where the diffuser is located to improve the ozone utilization rate and the pollutant removal rate by increasing the contact time between the fine bubbles of ozone gas and the high concentration wastewater.

However, the conventional ozone water treatment device requires a long contact time because gas-liquid contact occurs only through the vertical rise due to the buoyancy of the microbubbles of the diffused ozone gas. there was.

That is, the supplied ozone gas is not sufficiently used for the oxidation reaction, and the purification efficiency is low compared to the supply amount of ozone gas, and thus contaminants are not sufficiently removed because of low ozone utilization and pollutant removal rate, especially when treating high concentration wastewater. There was this.

Therefore, due to the problems described above, the conventional ozone water treatment apparatus has a limitation in purifying hardly decomposable substances such as high concentrations of wastewater or pesticide component materials such as DDT, PCB, and BHC.

An object of the present invention for solving the above problems is to maximize the oxidation reaction of ozone, recirculating ozone water treatment device that can purify the high concentration of wastewater in a short time by using a small amount of ozone gas and energy. To provide.

In addition, another object of the present invention is to provide a recirculating ozone water treatment apparatus capable of increasing the ozone utilization efficiency through recycling of a portion of the ozonated water and increasing the purification rate even in the case of a high concentration of wastewater.

Recirculating ozone water treatment apparatus of the present invention for achieving the above object, a raw water tank into which raw water is introduced or discharged; An ozone supplier for supplying ozone gas to the raw water introduced from the raw water tank; A complex reactor for homogeneously mixing the raw water supplied with the ozone gas so as to reduce the amount of dissolved ozone in the raw water by promoting the oxidation reaction of the ozone gas, and turbulizing the flow to generate ozonated water; And an ozone treatment tank into which the ozone treatment water flows in or out, wherein the raw water tank and the ozone treatment tank communicate with each other, such that the oxidation reaction of the ozone gas remaining in the ozone treatment water is highly contaminated by the raw water. A portion of the ozonated water of the ozone treatment tank is mixed with the raw water of the raw water tank and recycled so as to be promoted due to the concentration.

The raw water tank and the ozone treatment tank are each provided in an area divided by a partition wall installed in the center of the recycling tank provided in the form of a single tank, and a recycling port is formed in the partition wall so that the raw water tank and the ozone treatment tank are It may be provided to communicate with each other.

In addition, the recirculating ozone water treatment apparatus of the present invention includes a first mixed reactor and a first multi-jet reactor equipped in an ozone treatment tube that is a passage through which the raw water supplied with the ozone gas is transferred from the ozone supplier to the complex reactor, and The ozone treated water may further include a third multi-injection reactor provided in the ozone treated water feed pipe, which is a passage through which the ozone treated water is transferred from the complex reactor to the ozone treated water tank.

The first multi-injection reactor passes through the raw water supplied with ozone gas and is provided with a catching jaw, and is fixedly installed or separated inside the multi-spraying pipe by the catching jaw and has a plurality of penetrations through the upper and lower surfaces. At least one multi-injection unit provided with a hole or a through network, wherein at least one of the multi-injection unit is installed therein, and at least one spray plate provided with a plurality of through holes or through networks, and the lower surface and It may include a plurality of cleaning tools provided on the side to clean each of the one or more jet plate.

The complex reactor is equipped with a second mixing reactor, a porous spray plate or a mesh spray plate to mix the raw water supplied with ozone gas to be homogeneous, the second multi-jet reactor which changes the flow rate and pressure of the raw water supplied with ozone gas, And a rectifier for rectifying the raw water supplied with the ozone gas passing through the second mixed reactor and the second multi-jet reactor.

Recirculating ozone water treatment method of the present invention, the energy required for the water treatment is supplied to the raw water flows into the raw water tank; Supplying ozone gas to the raw water by an ozone supplier; A complex reactor mixing the raw water supplied with the ozone gas in a homogeneous manner so as to reduce the dissolved ozone amount of the raw water by promoting an oxidation reaction of the ozone gas, and turbulizing the flow to generate ozonated water; Introducing the ozone treated water into an ozone treated water tank; Mixing a portion of the ozonated water of the ozone treatment tank with the raw water of the raw water tank to promote oxidation of the ozone gas remaining in the ozone treatment water due to the high pollution concentration of the raw water; And recycling the ozonated water mixed with the raw water to pass through the complex reactor.

According to the recirculating ozone water treatment apparatus and the water treatment method of the present invention, a part of the ozone treated water is recycled to a recirculation port provided in the recirculating water tank, and the ozone gas remaining in the ozone treated water is used for purification of raw water and a part of the ozone treated water. By repeatedly purifying, the high concentration of wastewater can be purified with a small amount of ozone in a short time, and the ozone utilization efficiency can be maximized.

Therefore, it is possible to effectively purify the treatment of high concentration sewage and wastewater without using a large amount of ozone, and to reduce the cost of water treatment by using a stationary multi-injection reactor with low energy consumption. By using ozone gas as much as possible, it is not necessary to inject ozone gas repeatedly, so it is possible to realize small size compared to the treatment capacity.

In addition, it is possible to easily purify difficult-decomposable substances which are difficult to purify by the conventional ozone treatment technique, and to continuously purify the waste water and waste water.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

Hereinafter, a recirculating ozone water treatment apparatus according to a preferred embodiment of the present invention will be described in detail with reference to FIGS. 1 to 8.

As shown in FIG. 1, the recirculating ozone water treatment device according to a preferred embodiment of the present invention includes a raw water tank 100, a recirculation tank 200, an ozone feeder 300, and a combined reactor 400. do.

The raw water tank 100 temporarily stores raw water, which is a wastewater, so that a predetermined amount of raw water may be supplied to the water treatment apparatus even if the inflow of raw water changes. Raw water of the raw water tank 100 is supplied to the recirculation tank 200 along the raw water transport pipe 110 by the raw water pump (PP). At this time, the raw water pump (PP) may be provided with a flow meter (F) to measure the amount of raw water flowing into the recirculation tank (200).

The recirculation tank 200 introduces the raw water and the ozonated water purified by the raw water into ozone treatment, respectively, and mixes a portion of the ozonated water with the raw water to be recycled. Here, the recirculation means that the ozonated water is ozone treated again through the ozone supplier 300 and the combined reactor 400.
On the other hand, the raw water is ozone treated water while the ozone gas is injected and passes through the complex reactor 400, the injected ozone gas is oxidized vigorously as the flow is turbulent and mixed by the complex reactor 400 most of the time . However, a small amount of dissolved ozone gas may remain in the ozonated water that has undergone this process. As described above, when a portion of the ozonated water is mixed with raw water, the ozone gas remaining in the ozonated water is oxidized. It is promoted due to its high concentration of pollutants and is used for the purification of raw water.
That is, in the recirculating ozone water treatment device according to the preferred embodiment of the present invention, the utilization rate of ozone gas injected into the raw water and the removal rate of contaminants in the raw water are 100 through the recirculation structure for the combined reactor 400 and a portion of the ozonated water. Maximize close to%
As such, when all the injected ozone gas is used for the oxidation reaction, since there is almost no dissolved ozone gas in the final ozone treated water, there is no need to go through a separate process of removing the dissolved ozone gas in the ozonated water to prevent environmental pollution. Recirculating ozone water treatment apparatus according to the present invention is very efficient.

As shown in FIGS. 1 and 2, the recirculation tank 200 includes a partition wall 210, a raw water tank 220, and an ozone treatment tank 230.

The partition wall 210 is installed at the center of the recirculation tank 200 to divide the recirculation tank 200 into the raw water tank 220 and the ozone treatment water tank 230. One or more recirculation openings 211 communicating with the raw water tank 220 and the ozone treatment water tank 230 are formed in the partition wall 210.

At least one of the recirculation ports 211 allows a portion of the ozonated water in the ozone treatment tank 230 to be mixed with the raw water in the raw water tank 220, so that the ozone treatment water is subjected to the ozone treatment process together with the raw water again. Recycle part of.

The raw water tank 220 is a place where the raw water introduced from the raw water tank 100 is temporarily stored before ozone treatment. The raw water tank 220 is located on the left side of the recirculation tank 200, as shown in FIG.

Side of the raw water tank 220 is provided with a raw water discharge pipe 221 for discharging raw water for ozone treatment. The raw water is transferred to the ozone supplier 300 through the raw water discharge pipe 221 by receiving the power required for ozone treatment from the ozone treatment pump (OP). In addition, the raw water tank 220 is provided with an overflow pipe 222 for preventing the raw water from overflowing, and a drain pipe 223 used for emptying and repairing the raw water tank 220.

The recirculating ozone water treatment device may be provided to temporarily stop the operation when the raw water is discharged through the overflow pipe 222.

The ozone treatment tank 230 is a place where the ozone treatment water generated by ozone treatment is introduced from the complex reactor 400 and temporarily stored therein. The ozone treatment tank 230 is located on the right side of the recirculation tank 200, as shown in FIG.

A side of the ozone treatment tank 230 is connected to a treatment water discharge pipe 231 used to discharge the ozone treatment water, and a treatment water pump DP for transferring the ozone treatment water for further treatment such as filtration. The treatment transport pipe 232 is provided.

In addition, the ozone treatment tank 230 is provided with an overflow tube 233 for preventing the ozone treatment water from overflowing from the tank and a drain tube 234 used for emptying and repairing the ozone treatment tank 230. do.

The recirculating ozone water treatment apparatus may be provided to temporarily stop the operation when the ozone treatment water is discharged through the overflow pipe 233.

In a preferred embodiment of the present invention, the recirculation tank 200 is provided with a recirculation tank cover 240 thereon. The recirculation tank cover 240 is provided with a bubble discharger 240 to remove and discharge the bubbles by collecting various gases and bubbles generated from the raw water stored in the recirculation tank 200 and the recirculation tank 200 The pressure inside is kept stable. At this time, when a large amount of bubbles do not occur in the recirculation tank 200 may be provided with a respirator for maintaining a stable pressure of the recirculation tank 200 by discharging the gas instead of the bubble discharger (240).

In a preferred embodiment of the present invention, the recirculation tank 200 is implemented in the form of a partition wall is installed in the center of the rectangular parallelepiped, the raw water and the ozonated water can be stored respectively, a portion of the ozone treated water can be recycled If it is present form, it is not necessarily limited to this.

For example, the raw water tank 220 and the ozone treatment tank 230 may be provided separately, and a separate recirculation tube may be provided to communicate the raw water tank 220 and the ozone treatment tank 230. .

The ozone supplier 300 is implemented by an ejector method or a direct injection method, and supplies ozone generated from the ozone generator 310 to the raw water. When the ozone supply unit 300 is implemented in an ejector method, an ejector is installed such that ozone gas is sucked into the raw water by a difference in pressure generated from the ejector, thereby supplying ozone to the raw water.

When the ozone supplier 300 is implemented by a direct injection method, as shown in Figures 3a and 3b, in the shape of a tube installed to be perpendicular to the running direction of the raw water passing through the ozone treatment tube (350). It is provided.

In the ozone supply 300 according to the direct injection method of the recirculating ozone water treatment device according to the preferred embodiment of the present invention, four supply pipes 320 are installed at intervals of 90 degrees on the outer circumferential surface of the pipe. At the ends of the four supply pipes 320, supply holes 330 through which ozone gas is discharged are formed. In addition, one supply hole 330 is formed between the four supply pipes 320.

Therefore, the ozone supplier 300 is provided with eight supply holes 330, and ozone gas is supplied to the raw water through the supply hole 330. However, the shape of the ozone supplier 300, the shape and number of the ozone treatment tube 350, and the number of the supply holes 330 are not limited thereto. For example, the ozone supplier 300 may be implemented as one porous body having a spherical shape.

As shown in FIGS. 1 and 3A, the ozone treatment tube 350 provided with the ozone supplier 300 includes a first mixing reactor 351 and a first multiple injection reactor MR1a. That is, the raw water supplied with the ozone gas through the ozone supplier 300 passes through the first mixed reactor 351 and the first multi-jet reactor MR1a in turn.

On the other hand, before the raw water of the raw water tank 220 is supplied to the ozone supplier 300 through the raw water discharge pipe 221 is provided with a pressure gauge (P) for measuring the pressure of the raw water supplied to the ozone supplier (300) May be

The first mixing reactor 351 homogeneously mixes raw water supplied with ozone gas, thereby promoting oxidation of the ozone. The first multi-injection reactor (MR1a) changes the flow rate and pressure of the raw water supplied with ozone gas, vortex and turbulence the flow, and reversely mixes the ozone gas and raw water that are not completely reacted to oxidize the ozone. Promote the reaction.

The raw water supplied with ozone gas has a uniform distribution in the raw water of the supplied ozone gas while passing through the first mixing reactor 351, and the molecules and water of the ozone gas supplied while passing through the first multi-injection reactor MR1a. Molecules and waste materials collide violently, maximizing gas-liquid contact, thereby promoting oxidation reactions.

The first multi-injection reactor MR1a includes a multi-injection tube MR1-1 and a multi-injection unit MR1-2, as shown in FIGS. 4A and 4B. The multi-injection tube MR1-1 is installed in the ozone treatment tube 350 and passes through the ozone supplier 300 to pass raw water supplied with ozone gas.

The inside of the multi-injection tube MR1-1 is provided with a locking step MR1-1a for fixing the position of the multi-injection unit MR1-2. Flanges MR1-1b are provided at both ends of the multi-injection tube MR1-1 so that the multi-injection tube MR1-1 can be installed in the ozone treatment tube 350.

The multi-injection unit MR1-2 is assembled inside the multi-injection tube MR1-1, and rapidly changes the flow rate and pressure of raw water passing through the multi-injection unit MR1-2 to oxidize ozone. Promote the reaction. As shown in FIGS. 4A and 4B, the multi-injection unit MR1-2 is provided in the shape of a cylinder having a handle G on an upper surface thereof and a plurality of through holes H formed on the lower surface thereof. .

The multi-injection unit MR1-2 is provided with one or more jet plates MR1-2a provided parallel to the upper and lower surfaces at regular intervals therein. A plurality of through holes H are formed in the injection plate MR1-2a as shown in the upper and lower surfaces, respectively. In addition, a plurality of cleaning holes MR1-2b are provided on side surfaces of the multi-injection unit MR1-2 so as to clean the jet plate MR1-2a and the lower surface of the multi-jet unit MR1-2.

In the preferred embodiment of the present invention, the cleaning tool (MR1-2b) is implemented so that one is provided in a rectangular shape on one spray plate (MR1-2a), the shape and number is not limited thereto. For example, a pair of cleaning tools MR1-2b facing each other in a semi-ellipse shape may be provided.

The multi-injection unit MR1-2 is installed inside the multi-injection tube MR1-1, and the raw water flows therein. At this time, while the raw water passes through the plurality of through holes H of the multi-injection unit MR1-2, its path and flow rate change rapidly and become vortex-turbulent.

In this case, when solid foreign matter is mixed in the raw water, foreign matters having a predetermined size or more do not penetrate the through hole H and accumulate on the upper and lower surfaces and the injection plate MR1-2a. When a large amount of foreign matter is accumulated, the multi-injection unit MR1-2 is separated from the multi-injection tube MR1-1 by using the handle G, and the plurality of cleaning holes MR1-2b are used to clean the multi-injection unit MR1-2b. Can be.

In the first multi-injection reactor MR1a according to a preferred embodiment of the present invention, the upper and lower surfaces and the injection plate MR1-2a are provided in a plate shape having a plurality of through holes H, but are not limited thereto. For example, the upper and lower surfaces and the injection plate MR1-2a may be provided as one penetrating network.

In addition, the first multi-injection reactor (MR1a) according to a preferred embodiment of the present invention is implemented as an assembly type in which the multi-injection tube (MR1-1) and the multi-injection unit (MR1-2) can be assembled or separated However, the present invention is not limited thereto, and may be implemented as a fixed type as illustrated in FIG. 4C.

In the case of the fixed type, the first multi-injection reactor MR1a is provided in a shape in which the one or more injection plates MR1-2a are directly fixed to the multi-injection tube MR1-1. In this case, the jet plate MR1-2a may be provided as a penetrating network.

4A and 4B, the prefabricated multi-injection reactor is easy to separate and easy to clean, so it is preferable when the raw water contains a large number of foreign substances or the viscosity is high, and the fixed multi-multi as shown in FIG. 4C. Since the spray reactor is impossible to clean, it is preferable when there is little foreign matter or low viscosity in the raw water.

As described above, the first multi-injection reactor MR1a is a stationary type, which is composed of elements that consume less energy, and thus consumes less energy. However, the first multi-injection reactor MR1a is characterized in that the treatment efficiency for promoting oxidation reaction is very high.

On the other hand, the above-described complex reactor 400 homogeneously mixes the raw water mixed with ozone gas, and changes the flow rate and pressure to promote the purification of ozone. As shown in FIGS. 5 to 8, the complex reactor 400 includes a second mixed reactor 410, a second multi-jet reactor MR1b, and a rectifier 420.

The second mixing reactor 410 is similar in configuration to the first mixing reactor 351 provided in the ozone treatment tube 350 described above. In addition, the second multiple injection reactor MR1b is similar in configuration to the first multiple injection reactor MR1a provided in the ozone treatment tube 350 described above. Therefore, a detailed description of the second mixing reactor 410 and the second multi-jet reactor MR1b will be omitted.

The first mixture reactor 351 and the second multiple injection reactor MR1b are provided in the ozone treatment tube 350, respectively, but the second mixture reactor 410 and the second multiple injection reactor ( MR1b) is installed in one tank together with the rectifier 420 and is unitized as a combined reactor 400.

The rectifier 420 passes the second mixed reactor 410 and the second multi-jet reactor MR1b and uniformly rectifies the flow of the ozonated water purified by ozone treatment. The ozone treated water rectified as described above is introduced into the ozone treated water tank 230 through the ozone treated water pipe 450 provided at the upper portion of the complex reactor 400.

The lower portion of the composite reactor 400 is provided with a drain pipe 435 used to empty the composite reactor 400 during repair and cleaning.

The gas-liquid separator 430 is installed at the top of the complex reactor 400. The gas-liquid separator 430 separates gas and liquid to discharge gas generated during ozone treatment in the complex reactor 400 to maintain a constant pressure in the complex reactor 400. The gas-liquid separator 430 preferably uses a commercially available buzzer check valve.

The gas discharged through the gas-liquid separator 430 is discharged through the ozone decomposer 440 as a safe gas having a very low ozone concentration. When the concentration of the ozone decomposer 440 is not high, the use of activated carbon decomposition is generally used. However, the present invention is not limited thereto, and an ozone decomposer of thermal decomposition and catalytic decomposition may also be used.

In the recirculating ozone water treatment apparatus of the present invention, the complex reactor (horizontal type, 400) according to an embodiment may be connected to the ozone treatment tube 350 as shown in FIGS. 5 and 6. To be provided. In addition, according to the connection path of the ozone treatment tube 350, the second mixed reactor 410 and the second multi-jet reactor MR1b are provided.

The complex reactor 400 is provided such that the second mixed reactor 410, the second multi-injection reactor MR1b, and the rectifier 420 are installed one by one in the path of the introduced raw water, but are not limited thereto. It may be provided in plurality.

7 and 8 are combined reactor (vertical, 400) according to another embodiment, the ozone treatment tube 350 is provided to be connected to the top. The two embodiments of the complex reactor 400 described above are based on the pipe state of the ozone treatment tube 350 and the ozone treatment water pipe 450, but are not necessarily limited to these two embodiments. That is, according to the pipe state of the ozone treatment pipe 350 and the ozone treatment water pipe 450, the shape of the complex reactor 400 may be variously implemented.

The ozone treatment water pipe 450 communicates with the ozone treatment water so that the ozone treatment water can be transferred from the complex reactor 400 to the ozone treatment water tank 230. The ozone treated water pipe 450 is provided with a third multi-injection reactor MR1c to promote oxidation of ozone dissolved in the ozone treated water.

The third multi-injection reactor MR1c is similar in configuration to the first multi-injection reactor MR1a provided in the ozone treatment tube 350 described above. Therefore, a detailed description of the third multi-injection reactor MR1c will be omitted.

The ozone treated water transferred to the ozone treated water tank 230 through the ozone treated water pipe 450 is discharged through the treated water discharge pipe 231 or is transmitted through the treated water transport pipe 232. However, some of the ozonated water is mixed with the raw water of the raw water tank 220 through the recirculation port 211 as described above.

Hereinafter, with reference to Figure 9, looks at the recycle ozone water treatment method of the present invention that is the operation of the recycle ozone water treatment apparatus according to a preferred embodiment of the present invention.

First, the raw water stored in the raw water tank 100 is supplied with energy required for water treatment and flows into the raw water tank 220 of the recirculation tank 200. (s100) At this time, the bubble discharger of the recirculation tank cover 240 241 or the respirator discharges the gas and bubbles present at the top of the recirculation tank (s200).

Next, the ozone supplier 300 installed in the ozone treatment tube 350 supplies ozone gas to the raw water pressurized and discharged from the raw water tank 220. (s300).

In addition, the ozone supplied raw water passes through the first mixing reactor 351 and the first multiple injection reactor MR1a in order to promote the oxidation of ozone. In addition, the composite reactor 400 homogeneously mixes the raw water mixed with the ozone, and changes the flow rate and pressure to promote the oxidation reaction of ozone to produce ozonated water.

Specifically, the raw water in which ozone gas is dissolved is mixed homogeneously while passing through the second mixed reactor 410 of the complex reactor 400 (s400). Next, the raw water passed through the second mixed reactor 410 is mixed. As the flow rate and pressure rapidly change while passing through the second multi-injection reactor MR1b of the complex reactor 400, the oxidation reaction of ozone is promoted. (S500) Then, the second multi-injection reactor (MR1b) is passed through. Raw water passes through the rectifier 420 and the flow becomes constant.

Thereafter, the ozone treatment water generated in the complex reactor 400 is introduced into the ozone treatment tank 230 of the recirculation tank 200. (s700) Next, the ozone treatment water of the ozone treatment tank 230 is recycled ( 211) is mixed with the raw water of the raw water tank 220 by a predetermined amount. (S800)

Here, the ozonated water introduced into the raw water tank 220 undergoes an ozone treatment process again with the raw water, and the ozonated water temporarily stored in the ozone treated water tank 230 is the treated water discharge pipe 231. Is discharged through, or is transferred to the next processing step through the treatment transport pipe 232. (s900)

Although the present invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical spirit of the present invention, and such modifications and variations belong to the appended claims. will be.

1 is a schematic diagram of a recirculating ozone water treatment apparatus of the present invention,

Figure 2 is a perspective view of the recirculation tank provided in the recirculating ozone water treatment apparatus of the present invention,

Figure 3a is a side view of the ozone feeder provided in the recirculating ozone water treatment apparatus of the present invention,

Figure 3b is a front view of the ozone feeder provided in the recirculating ozone water treatment apparatus of the present invention,

4A is a cross-sectional view of a first multiple jet reactor according to Embodiment 1 of a recirculating ozone water treatment apparatus of the present invention;

Figure 4b is a perspective view of a multi-injection unit of the first multi-injection reactor according to an embodiment of the recirculating ozone water treatment apparatus of the present invention,

Figure 4c is a cross-sectional view of the first multi-injection reactor according to another embodiment of the recirculating ozone water treatment apparatus of the present invention,

5 is a plan view of a combined reactor according to one embodiment of a recirculating ozone water treatment apparatus of the present invention;

6 is a cross-sectional view of A-A shown in FIG.

7 is a plan view of a combined reactor according to another embodiment of a recirculating ozone water treatment apparatus of the present invention;

8 is a cross-sectional view of B-B shown in FIG.

9 is a flow chart of the recirculating ozone water treatment method of the present invention.

＊ Explanation of symbols for main part of drawing ＊

100: raw water tank 110: raw water pipe

200: recycling tank 210: partition wall

211: recirculation outlet 220: water tank

221: raw water discharge pipe 230: ozone treatment tank

231: treated water discharge pipe 232: treated water transport pipe

240: recirculation tank cover 241: foam discharger

300: ozone supply 310: ozone generator

350: ozone treatment tube 351: first mixed reactor

400: mixed reactor 410: second mixed reactor

420: rectifier 430: gas-liquid separator

440: ozone decomposer 450: ozone treated water pipe

PP: Raw Water Pump OP: Ozone Treatment Pump

DP: treated water pump MR1a: first multiple injection reactor

MR1-1: Multi-injector MR1-1a: Hanging Jaw

MR1-2: Multi-injection unit MR1-2a: Injection plate

MR1-2b: Cleaning tool MR1b: Second multi-jet reactor

MR1c: third multi-injection reactor H: through hole

G: Handle F: Flow Meter

P: pressure gauge

Claims (6)

In the device for supplying and purifying ozone gas to raw water, which is waste water, A raw water tank into which the raw water is introduced or discharged; An ozone supplier for supplying the ozone gas to the raw water introduced from the raw water tank; A complex reactor for homogeneously mixing the raw water supplied with the ozone gas so as to reduce the amount of dissolved ozone in the raw water by promoting the oxidation reaction of the ozone gas, and turbulizing the flow to generate ozonated water; And Including; ozone treatment tank in which the ozone treatment water is introduced or discharged; The raw water tank and the ozone treatment tank, By communicating with each other, a portion of the ozonated water of the ozone treatment tank is mixed with the raw water of the raw water tank and recycled so that the oxidation reaction of the ozone gas remaining in the ozone treatment water can be promoted due to the high pollution concentration of the raw water. Recirculating ozone water treatment device, characterized in that. The method of claim 1, The raw water tank and the ozone treatment tank, Is provided in each of the areas divided by the partition wall installed in the center of the recirculation tank provided in the form of one tank, the partition wall, The recirculating ozone water treatment device, characterized in that the recirculation port is formed so that the raw water tank and the ozone treatment tank is in communication with each other. The method according to claim 1 or 2, A first mixed reactor and a first multiple injection reactor provided in an ozone treatment tube that is a passage through which the raw water supplied with the ozone gas is transferred from the ozone supplier to the complex reactor; And A third multi-injection reactor provided in the ozone treated water feed pipe which is a passage through which the ozone treated water is transferred from the complex reactor to the ozone treated water tank; The recirculating ozone water treatment device further comprises. The method of claim 3, The first multi-injection reactor, A multi-injection tube passing through the raw water supplied with ozone gas and having a stopping jaw; And At least one multi-injection unit fixedly installed or separated in the multi-injection pipe by the locking jaw, and having a plurality of through holes or through networks at upper and lower surfaces thereof; Including, but one or more of the multi-injection unit, One or more jet plates installed therein and provided with a plurality of through holes or through networks; A plurality of cleaning holes provided on the side to clean the lower surface and the at least one jet plate, respectively Recirculating ozone water treatment apparatus comprising a. The method according to claim 1 or 2, The complex reactor, A second mixing reactor for mixing the raw water supplied with ozone gas to be homogeneous; A second multi-jet reactor equipped with a porous jet plate or a net jet plate to change the flow rate and pressure of raw water supplied with ozone gas; And A rectifier for rectifying raw water supplied with ozone gas passing through the second mixed reactor and the second multi-jet reactor; Recirculating ozone water treatment apparatus comprising a. Supplying energy for water treatment so that raw water flows into the raw water tank; Supplying ozone gas to the raw water by an ozone supplier; A complex reactor mixing the raw water supplied with the ozone gas in a homogeneous manner so as to reduce the dissolved ozone amount of the raw water by promoting an oxidation reaction of the ozone gas, and turbulizing the flow to generate ozonated water; Introducing the ozone treated water into an ozone treated water tank; Mixing a portion of the ozonated water of the ozone treatment tank with the raw water of the raw water tank to promote oxidation of the ozone gas remaining in the ozone treatment water due to the high pollution concentration of the raw water; And Recycling the ozonated water mixed with the raw water to pass through the complex reactor; Recirculating ozone water treatment method comprising a.

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