KR100898810B1 - River-water purifying and recycling system for removal of odor and improvement of water quality using multiple gas-liquid contact apparatus - Google Patents

Abstract

The present invention relates to a system for purifying and recycling river water by using ozone in order to stably provide river water in Guncheon Stream. More particularly, the present invention relates to a system in which a sand filter is installed under a river underwater, Liquid contact with the ozone contact vessel in the ozone contact vessel during the reaction with the ozone in the ozone contact vessel to maximize the utilization rate of ozone and to save energy , A river water purification and recycling system to which a multi-media liquid contact apparatus is applied for the removal of odor of a river and the improvement of water quality.

Multi-medium liquid contact device, sand filtration device, ozone contact tank, dissolved ozone control device

Description

Technical Field [0001] The present invention relates to a water purification and recycling system for a river water purification and recycling system using a multi-

The present invention relates to a system for purifying and recycling river water by using ozone in order to stably provide river water in Guncheon Stream. More particularly, the present invention relates to a system in which a sand filter is installed under a river underwater, Liquid contact with the ozone contact vessel in the ozone contact vessel during the reaction with the ozone in the ozone contact vessel to maximize the utilization rate of ozone and to save energy , A river water purification and recycling system to which a multi-media liquid contact apparatus is applied for the removal of odor of a river and the improvement of water quality.

Generally, in order to stably supply the river maintenance water of the stream in Guncheon stream, the downstream water is pumped to the upstream side, the advanced sewage treated water is sent upstream, or the water is drawn from the river and purified And to the river.

However, the above-described conventional methods have a problem in that they can not be applied to a case where a lot of power is consumed and there is no fundamentally a way of holding the river or there is no way to draw water.

On the other hand, ozone has a strong oxidizing power (potential difference: 2.07 V) and is widely used for water treatment because it has excellent effects such as sterilization, disinfection, deodorization and decolorizing effect.

However, since ozone is a gas having a relatively low solubility in water, ozone should be dissolved by using a vapor-liquid mixing apparatus when it is applied to water treatment. In addition, ozone is very unstable in a liquid state and is decomposed in a relatively short time. The use efficiency of ozone has been a problem in the water treatment using water.

Accordingly, in the field of water treatment using ozone, in order to dissolve ozone and to perform a reaction treatment, a porous diffuser is installed at the base of the water to disperse ozone with a fine particle to dissolve the bubbles while rising, Injector system, pressurization pump system, turbine-mixer system, etc. are used.

However, the most commonly used acid-based process has a disadvantage in that ozone dissolves at a rate of about 20% and wastes a considerable amount of ozone. In addition, other methods such as a pressurizing pump method and an injector method have a simple process, There is a problem that the efficiency is low or the power is large.

The present invention has been made to solve the limitations and problems of the prior art as described above, and it is an object of the present invention to provide a water filtration apparatus, The purpose of this study is to make the river water primarily purified before the ozone oxidation.

In addition, the filtered river water is collected in the water collecting tank 220 and the ozone and the filtered water are subjected to the ozone oxidation reaction in the ozone oxidation systems 300, 310, 320, 330, 400 and 410 to remove the odor of the river water and purify And then the treated water is pumped upstream to flow downstream to purify and recycle the stream water and to keep the stream water stable.

Further, in particular, a multi-media liquid contact device is mounted in an ozone contact tank in which ozone oxidation treatment is carried out, so that gas-liquid contact can be repeatedly performed to increase the utilization rate of ozone, Circulating ozone can be sufficiently dissolved in the filtered water, thereby maximizing the utilization rate of ozone.

Another object of the present invention is to provide a multi-media liquid contact device inside the ozone contact tank, thereby simplifying the facility and saving power required for driving.

According to an aspect of the present invention, there is provided a system for purifying stream water through ozone oxidation in an ozone contact tank, the system comprising: an ejector installed at an inner upper portion of the ozone contact tank; An ozone supply pipe connected to one side of the ejector; And a vortex generating tube having a spiral propeller fixedly mounted on the lower portion of the ejector, the ejector having a predetermined clearance and being inserted into the ejector. It provides a stream water purification and recycling system with multi-media contact equipment.

A sand filtration device installed under the underwater pressure of the river to enable filtration by natural hydraulic pressure; A water collecting tank for storing the filtered river water in the sand filtration apparatus; An ozone generator for generating ozone; An ozone contact vessel in which an ozone oxidation reaction occurs by mounting a multi-media liquid contact device inside the ozone generator so that ozone supplied from the ozone generator is dissolved in contact with filtered water supplied from the water collection vessel; A dissolved ozone control device for removing ozone dissolved in the treated water purified in the ozone contact tank; An ozone removing device for stably removing ozone generated in the ozone contact tank and the dissolved ozone control device; A pumping tank in which the treated water subjected to the ozone oxidation treatment is collected after passing through the dissolved ozone control device; And a transfer pump for transferring the treated water collected in the pumping tank to the upstream of the stream. The present invention provides a system for cleaning and recycling a stream water to which a multi-media liquid contact apparatus for removing odors and improving water quality is applied.

As described above, according to the present invention, it is possible to provide a sand filtration device below the river underwater and to allow the river water to pass through the sand filter by natural oil pressure without any additional power supply, thereby stably removing the suspended solid .

Further, in ozone treatment of the river filtration water through the ozone oxidation system, repetitive gas-liquid contact can be made in the multi-phase liquid contact device by forming the flow velocity and vortex of the ejection by mounting the multi- As a result, the efficiency of ozone dissolution and purification treatment through the ozone can be improved, and the utilization rate of ozone can be improved to 97% or more.

As shown in the following table, in the present invention, it is possible to repeatedly perform gas-liquid contact between ozone and filtered water by means of a multi-media liquid contact device. Normally, when operating the ejector with a 10 HP pump, a maximum of 200 LPM (Liter per minute) However, when the multi-stage liquid contact apparatus of the present invention is used, gas-liquid contact exceeding 200 LPM can be achieved even by the ejector power of the 2HP pump, so that the power required for the oxidation treatment can be saved by 80% or more.

Pump Power (HP) The gas-liquid contact (LPM) Gas-liquid contact (LPM) by multi- 10 200 696 7.5 147 574 5 101 382 3 57 297 2 38 215 One 19 132 0.5 7 74

In addition, the purified water, such as odor removal and water quality improvement through ozone oxidation, is pumped to the upstream of the stream after separation of ozone and removal of dissolved ozone, so that the present invention can stably maintain the river water of the stream , And the effect of enabling river water to be recycled in an environmentally friendly manner is derived.

The features of the present invention will be more clearly understood from the following detailed description based on the accompanying drawings.

FIG. 1 (a) is a view showing a structure of a whole system according to the present invention. FIG. 1 (a) is a view showing a structure of a whole system of the present invention. And Fig. 1 (b) is a hydraulic system diagram of the present invention.

As shown in FIG. 1 (a), the present invention includes: a sand filtration apparatus 110 installed under a river underwater; A primary pumping tank 200 for receiving filtered river water (hereinafter referred to as "filtered water") that has passed through the sand filtration device; A water collecting tank 220 to which a predetermined level of filtered water is supplied from the primary pumping tank 200; An ozone generator 400 for generating ozone; A pure oxygen supply device 410 for supplying oxygen to the ozone generator 400; An ozone contact pump 330 for pumping filtered water flowing into the water collecting tank 220 and ozone supplied from the ozone generator 400; An ozone contact tank 300 in which the ozone supplied from the ozone contact pump 330 is contacted with and dissolved in the filtrate water to perform ozone oxidation reaction; An ozone removing device 310 for stably removing ozone generated in the ozone contact tank 300; A multi-media liquid contact device (320) for repeatedly causing gas-liquid contact in the ozone contact tank (300); A dissolved ozone control device 500 for controlling the dissolved ozone remaining in the treated water treated in the ozone contact tank 300; And a second pumping tank 600 and a treated water transfer pump 620 for pumping the treated water from which dissolved ozone has been removed to the upstream of the stream.

In particular, the present invention is a system for purifying river water using ozone, comprising: the ozone contact tank 300; An ozone depleting apparatus 310; A multi-media liquid contact device (320); An ozone generator 400; A pure oxygen supply device 410; And the ozone contact pump 330 is composed of the ozone oxidation systems 300, 310, 320, 330, 400 and 410.

Specifically, the sand filtration apparatus 110 is installed under the underwater pressure of the river so that filtration can be performed by natural hydraulic pressure without any additional power to remove the suspended matters.

The primary pumping tank 200 is a water intake tank for the filtered water passing through the sand filtration apparatus 110. When the filtered water reaches a certain water level, the water level meter 210 is installed. 220). ≪ / RTI >

The water collecting tank 220 is a storage device for ozone oxidation treatment of the filtered water supplied from the primary pumping tank 200. A water level meter 230 is installed in the water collecting tank 220 to measure the level of the storage fluid. And the amount of the filtered water supplied to the ozone contact tank 300 can be adjusted. The filtered water in the water collecting tank 220 is pumped and supplied to the ozone contact tank 300.

The ozone contact tank 300 is an apparatus in which filtered water and ozone are contacted and melted to cause a reaction. The ozone contact tank 300 is a device that reacts with contaminants such as organic matters, inorganic substances, and pathogenic microorganisms in the filtered water due to the oxidation action of dissolved ozone in the filtered water flowing into the ozone contact tank Are oxidized and sterilized, so that the filtered water can be purified.

In the meantime, a multi-media liquid contact device 320 is mounted in the ozone contact tank 300. The multi-media liquid contact device 320 is an apparatus for increasing the utilization rate of ozone by allowing the ozone and the filtered water to repeatedly contact and react.

Specifically, the multi-media liquid contact apparatus 320 is provided with a vortex generating tube equipped with a fixed spiral propeller for generating a vortex. The vortex is generated in the fixed spiral propeller due to the hydraulic pressure and speed of the eject, And vortex are applied in combination to allow the unreacted ozone to repeatedly contact with the filtered water to increase the utilization rate of ozone.

The ozone contact tank has a treatment water circulation supply pipe to circulate the treated water in the ozone contact tank, thereby maximizing the utilization rate of the ozone.

The ozonizer 310 removes unreacted ozone from the ozone contact vessel 300 and is connected to the ozone contact vessel 300.

The ozone generator 400 is a device for stably supplying high-concentration ozone to the ozone contact tank 300. The ozone generator 400 is a water electrode system in which oxygen is passed between a dielectric member through which electricity flows and a discharge electrode to separate oxygen molecules into corona discharge to form ozone, A pure oxygen supply device 410 is connected. Meanwhile, it is preferable that the ozone generator is a water electrode type, but it is needless to say that an ultraviolet ray irradiator or an electrolyzer having a UV lamp, which is a conventional ozone generator, may be installed.

The ozone contact pump 330 pumps filtered water flowing into the water collecting tank 220 and ozone supplied from the ozone generator 400.

Meanwhile, the dissolved ozone control device 500 is a device for removing ozone dissolved in the ozone oxidation treatment water in the ozone contact tank 300. The dissolved ozone control device 500 includes manganese dioxide in an amount of 1 to 10 %, And a connection pipe is formed so as to collect the ozone gas and send it to the ozone remover 310. The ozone removing device 310 is provided with a connection pipe.

The dissolved ozone control device 500 is configured in an upward flow type in order to stably remove sludge and dissolved ozone generated in a purifying process through gas-liquid contact, so that the flow of the treated water supplied from the ozone contact tank The water is released and the backwash is automatically generated to prevent the clogging.

The second pumping tank 600 is a device for collecting the treated water that has passed through the dissolved ozone control device and is equipped with a water level meter 610. The purified water collected in the second pumping tank 600 is supplied to the process And is transferred to the upstream of the stream through the water transfer pump 620. [

2 is a structural view of the sand filtration apparatus 110 according to an embodiment of the present invention.

The sand filtration apparatus 110 shown in FIG. 2 comprises a pair of filtration units 120 (a) and two filtration units 120 (b), and each of the filtration tanks includes a sandwiching upper support network 111 and a lower support network 112 ), Which are divided into three layers.

The layer between the upper supporting net 111 and the lower supporting net 112 is sandwiched with a filter medium and sandwiched between the upper supporting net 111 and the upper supporting net 111 of the filtration 120 (a) and the filtration 120 (b) The height of the filter material layer filled in each of the filtration tanks can be adjusted by configuring the layer spacing between the lower supporting networks 112 differently. Accordingly, it is possible to adjust the filtration rate of the river water through the sand filtration apparatus 110 by adjusting the height of the layer between the upper support network 111 and the lower support network 112 of the filtration tank according to the water quality of the river water,

The aeration device 113 installed at the lower end of the sand filtration device 110 is formed to reach a height at which the lower support network 112 is located and contacts the lower support network 112. If the sand filtration device is clogged, .

The lower layer of the sand filtration apparatus 110 is provided with a connection port 115 for providing a passage through which filtered water can be collected. The filtration unit 120a and the filtration unit 120b ), And a plurality of through-holes 114 are formed in the bottom of the bottom of the sand filter material layer.

2, a sand filtration apparatus 110 including a pair of filtration units 120 (a) and two filtration units 120 (b) is shown. However, the present invention is not limited thereto. The number of the filtration tanks can be increased or decreased according to the size of the filtration tank and the height of the upper support network 111 and the lower support network 112 of the filtration tanks can be different.

3 is a longitudinal sectional view according to an embodiment of the multi-media liquid contacting apparatus 320. As shown in FIG.

As shown in FIG. 3, the multi-media liquid contact apparatus 320 is mounted inside the ozone contact tank 300. An ozone supply tube 331 for supplying ozone generated from the ozone generator is connected to one side of the ejector 221. The ozone supply tube 331 is connected to the ozone supply tube 331, . On the other hand, the ejector 221 provided in the ozone contact tank 300 has a lower portion formed at the upper end of the vortex generation tube 321 provided in the ozone contact vessel, while maintaining a certain clearance with the vortex generation tube, And a spiral propeller 322 is fixedly mounted on the vortex generation pipe 321. The spiral-

The vortex generation pipe 321 has a structure in which the upper and lower ends thereof are opened to allow fluid to flow therein. It is preferable that the vortex generation tube is installed so that the upper end thereof is positioned at the same height as or lower than the height of the partition wall of the ozone contact tank. Also, although not shown in the drawings, the vortex generating tube is fixedly mounted in connection with a part of the ozone contact tank.

More specifically, the operation principle of the multi-media liquid contact apparatus mounted on the ozone contact tank is described as follows. Vacuum is formed at the end of the ejector while the filtered water is ejected from the ejector 221, ozone is introduced from the ozone supply pipe 331, The ozone is ejected into the ozone contact tank with primary mixing. On the other hand, in addition to the filtration water and ozone being supplied through the ejector and the ozone supply tube formed at the end portion thereof, the flow of the fluid into the multi-media liquid contact device can be prevented by the ozone supplied from the ozonizer, It is also possible to select a path which is pumped after being mixed in the ozone contact pump and then introduced into the ozone contact tank through the ejector.

Thus, the fluid that has been mixed with ozone and mixed and discharged passes through the spiral-shaped propeller 322 of the vortex generating tube 321, and vortex is generated without supplying any other power due to the flow rate and pressure of the ejection. At this time, filtered vapors and ozone have a repetitive contact opportunity due to the generated vortex, so that the supplied ozone can be sufficiently dissolved in the filtered water.

Due to the pressure of the filtered water exiting the vortex generating tube, the filtered water in the ozone contact tank below the vortex generating tube rises and flows down from the outside of the vortex generating tube and flows downward. At this time, The ozone generated by the ozone generating unit and the vortex generating tube is re-introduced into the gap between the vortex generating tube and the ejector by the flow of the ozone and the filtered water. Thus, the ozone once passes through the vortex generating tube, .

At this time, since the ozone existing in the upper part of the ozone contact tank flows into the ozone contact tank due to the flow and pressure of the filtered water downwardly moving upward in the ozone contact tank, the ozone usage efficiency can be increased.

Further, the ejector 221 is connected to the inflow pipe 302 to supply filtered water from the water collecting tank, or filtered water and ozone are mixed and supplied from the ozone contact pump. The circulation pipe 301 may be connected to the ejector 221 together with the inflow pipe 302. Accordingly, one end of the circulation supply pipe 301 is connected to the ejector 221, and the other end is connected to the ozone contact tank 300, so that the fluid in the ozone contact tank can be supplied again to the ejector. That is, even if ozone is not additionally supplied through the ozone supply pipe, the fluid in the ozone contact tank is returned to the ejector through the circulation supply pipe, thereby allowing the ozone and the filtered water to flow once, .

Therefore, the circulation supply pipe is operated according to the amount and condition of the filtered water requiring ozone treatment, thereby circulating the ozone and the filtered water in the ozone contact tank, thereby improving the efficiency and effectiveness of the ozone oxidation treatment. The ozone oxidation treatment in the ozone contact tank through the operation of the contact device is performed for 10 to 15 minutes.

On the other hand, in the ozone contact tank, there is a partition wall 305, and ozone is dissolved in the filtered water by the operation of the multi-media liquid contact device, and after the ozone oxidation process, the overflowed process water can be transferred through the process water discharge pipe 304 . However, the position of the process water discharge pipe is not limited to that shown in Fig. 3, and the process water discharge pipe can be installed at the lower side portion of the ozone contact tank, so that the process water in the ozone contact tank can be discharged have.

In addition, although FIG. 3 shows one multi-media liquid contact apparatus mounted in the ozone contact tank, one or more multi-liquid liquid contact apparatuses may be installed and operated depending on the volume of the ozone contact tank.

Therefore, by providing the multi-media liquid contact apparatus 320, not only the primary contact reaction with the filtered water flowing into the ozone contact tank 300 but also the contact reaction through the ejector, the contact reaction by the eddy current, The fluid in the ozone contact tank is circulated by the pressure of the fluid exiting the generation tube, so that the ozone and filtration water are in multiple contact with each other, thereby increasing the dissolution rate of the ozone. Even if the ozone contact tank is not provided with an agitator, So that the ozone oxidation reaction occurs effectively in the ozone contact tank.

Accordingly, the opportunity and frequency of contact between the ozone and the filtered water are increased through the multi-media liquid contact device 320, the ozone sufficiently dissolves in the filtered water, and the oxidation treatment of the filtered water by the ozone dissolved in the ozone contact tank 300 So that contaminants such as organic matters, minerals and pathogenic microorganisms in the filtered water are oxidized and sterilized to purify the filtered water.

4 is a longitudinal sectional view of the dissolved ozone control apparatus 500 according to an embodiment of the present invention.

4, the dissolved ozone control device 500 is largely divided into three layers by a support network 506 and divided into three chambers by a separation membrane 507 which vertically divides the three layers. Divided, and operated upwards.

Specifically, when the treated water supplied from the ozone contact tank 300 flows into the lower end of the dissolved ozone control unit 500 through the treated water inflow inlet 501, the dissolved water moves upwardly and the manganese dioxide is mixed with 1 to 10% After the ozone decomposition reaction has occurred through the intermediate dissolved ozone removal layer 502 filled with the ozone remover, the treated water in which dissolved ozone has been removed through the outflow pipe 505 connected to the upper side, Lt; / RTI >

On the other hand, when the inflow of the treated water supplied from the ozone contact tank 300 to the dissolved ozone control device 500 is stopped, backwash occurs automatically due to the water being drained through the discharge pipe 503 located at the lower end.

Although not shown in FIG. 4, the dissolved ozone control apparatus 500 is provided with a connection pipe in the lid 504 so as to collect the ozone gas and send it to the ozone remover 310.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be appreciated that one embodiment is possible. Accordingly, the true scope of the present invention should be determined by the technical idea of the claims.

1 (a) and 1 (b) are a block diagram and a repair system diagram showing the construction of one embodiment of a river water purification and recycling system to which a multi-media liquid contact apparatus for removing river odors and water quality according to the present invention is applied.

2 is a structural view of one embodiment of a sand filtration apparatus 110 according to the present invention.

3 is a longitudinal sectional view of an embodiment of a multi-media liquid contact apparatus 320 according to the present invention.

4 is a longitudinal sectional view of an embodiment of the dissolved ozone control apparatus 500 according to the present invention.

Description of the Related Art

110: Sand filtration device 111:

112: lower supporting network 113: aeration device

114: through hole 115:

120 (a): 1 filtration 120 (b): 2 filtration

200: primary pumping tank 220: water collecting tank

221: Ejector 300: Ozone contact tank

301: circulation supply pipe 302: inlet pipe

303: Transfer valve 304: Process water outlet pipe

305: partition wall 310: ozone depleting device

311: Ozone gas delivery line 320: Multi-media liquid contact device

321: vortex generating tube 322: helical propeller

330: ozone contact pump 331: ozone supply pipe

400: ozone generator 410: pure oxygen supplier

500: Dissolved ozone control device 501: Processed milk infusion

502: dissolved ozone removing layer 503: discharge pipe

504: Dissolved ozone control device lid 505: Outflow tube

506: Supporting network 507: Membrane

600: Secondary pumping tank 620: Processed water transfer pump

210, 230, 610: water gauge

Claims (10)

A system for purifying stream water through ozone oxidation in an ozone contact tank, The ozone contactor includes a water stream ejector installed at the upper end of the ozonization contact tank; An ozone supply pipe connected to one side of the ejector; And at least one multi-media liquid contact device comprising a vortex generating tube having a structure in which an ejector is installed at a lower portion of the ejector and the upper and lower ends are opened to allow the fluid to pass therethrough and a spiral propeller is fixedly installed inside The system for the purification and recycling of river water has been applied to the removal of odors in the river and the improvement of water quality. delete delete The method according to claim 1, Wherein the ozone contact tank further comprises a circulation supply pipe connecting one side of the ozone contact tank and the ejector so as to circulate and supply the fluid ejected from the ejector to the ejector. Stream water purification and recycling system. A sand filtration device installed below the river underwater to allow the river water to be filtered by natural hydraulic pressure; A water collecting tank for storing the filtered river water in the sand filtration apparatus; An ozone generator for generating ozone; An ozone contact vessel in which an ozone oxidation reaction takes place by mounting a multi-media liquid contact device in which ozone supplied from the ozone generator is brought into contact with and dissolved in the filtered river water supplied from the water collection vessel; A dissolved ozone control device for removing ozone dissolved in the treated water purified in the ozone contact tank; An ozone removing device for stably removing ozone generated in the ozone contact tank and the dissolved ozone control device; A pumping tank in which the treated water subjected to the ozone oxidation treatment is collected after passing through the dissolved ozone control device; And a feed pump for pumping the treated water collected in the pumping tank upstream of the stream, The multi-media liquid contact apparatus comprises a stream water ejector installed at an upper end of an ozone contact tank, an ozone supply pipe connected to one side of the ejector, and an ejector disposed at a lower portion of the ejector with a predetermined gap therebetween. And a vortex generating tube formed with an open structure and having a spiral propeller fixedly mounted therein. The stream water purification and recycling system employing a multi-media liquid contact device for stream odor removal and water quality improvement. 6. The method of claim 5, The sand filtration device comprises: a connection port for providing a passage through which the filtered water can escape; An aeration device installed on the floor for aeration when sludge is settled; An upper support network and a lower support network installed at upper ends of the connectors and the aerator to divide the layers of the sand filtration apparatus; And at least one filtration tank made of a filter material filled between the upper support network and the lower support network and adjusting the height of the filter medium layer to be filled therein by adjusting a gap between the upper support network and the lower support network. Streamwater purification and recycling system with multi - media contact system for odor removal and water quality improvement. 6. The method of claim 5, The dissolved ozone control device is configured to operate in an upward flow mode by providing a treated water inflow inlet at a lower portion and a dissolved ozone removing layer in which manganese dioxide is mixed at 1 to 10% as an inner intermediate layer, Streamwater purification and recycling system with multi - media contact device for river odor removal and water quality improvement. delete 8. The method according to any one of claims 5 to 7, Wherein the ozone contact tank further comprises a circulation supply pipe connecting one side of the ozone contact tank and the ejector so as to circulate and supply the fluid ejected from the ejector to the ejector. Stream water purification and recycling system. delete

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