KR100616522B1 - A contact reacting mixer by ozone gas - Google Patents

Abstract

The present invention relates to an ozone contact reaction mixer for purifying waste water by contacting and mixing ozone with waste water, the mixing part for sucking ozone from the outside by rotating the impeller and mixing it with the waste water introduced from the waste water inlet pipe; Aging / reaction section that oxidizes contaminants contained in the waste water by making a bend in the flow path of the mixed ozone / wastewater mixture, and waste ozone gas gas which is naturally eluted from the mixture aged and reacted by the aging / reaction section. A casing that separates and discharges water, and is a casing surrounding the outside of the impeller, the guide for discharging the mixed liquid of the ozone / wastewater on the side in an oblique direction to the ejection direction from the impeller and discharging it out of the casing. It relates to an ozone contact reaction mixer, characterized in that it further comprises a casing portion comprising a portion, wastewater To maximize the mixing and aging, the reaction of ozone, it is possible to increase the purification efficiency of the waste water.

Description

OCON CONTACT REACTING MIXER BY OZONE GAS}

1 is a cross-sectional view schematically showing an ozone contact reaction mixer according to the present invention.

2 is a perspective view and a cross-sectional view of an impeller casing containing an impeller according to the present invention.

3A is a perspective view of a gear portion surrounding the impeller casing according to the present invention.

3b is a plan view of an impeller casing according to the invention.

Figure 3c is a plan view of the assembled state of the impeller, the impeller casing and the gear unit according to the present invention.

4 is a perspective view and a cross-sectional view of the impeller according to the present invention.

5 is a perspective view and a cross-sectional view of the waterway blocking frame and the waterway protection frame installed in the aging and reaction unit according to the present invention.

6 is a perspective view and a cross-sectional view of the waterway blocking frame installed in the separation discharge unit according to the present invention.

7 is a perspective view and a cross-sectional view of the vortex membrane frame installed inside the separation discharge unit according to the present invention.

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

10: solution gas separation frame 20: wastewater inlet pipe

30: discharge pipe 40: electric motor

50 impeller 51 upper feather

52: lower feather 60: impeller casing lid

70 impeller casing 71 guide part

80: ozone suction pipe 90: waterway blocking frame

91: 92, 93, 102, 103: cylindrical membrane

94: center inlet 101: upper surface

104: support 100: waterway protection frame

110: waterway blocking frame 120: waterway protection frame

130: vortex membrane frame 131: central inlet pipe

140: T pipe socket 150: pressure gauge

160: gas blowing valve 170: main body

180: shaft bearing casing 190: union joint

200: cleaning valve 210: motor shaft pulley

220: gear portion 221: gear

222: gear shaft 230: motor base

240: check valve (check valve) 250: solenoid valve (automatic)

260: flexible joint 270, 280, 290: flange

300: mixing section 310: first aging, reaction section

320: second aging, reaction unit 330: separate discharge unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ozone contact reaction mixer used in a wastewater treatment apparatus for purifying wastewater, such as a bathroom or a factory. More specifically, the ozone contact for oxidizing pollutants ionized in wastewater with ozone to purify wastewater It relates to a reaction mixer.

In the case of a conventional ozone contact reaction mixer using an air compressor, a method of purifying wastewater by discharging ozone gas to an acid pipe which is a bubble generator and supplying it to the wastewater, reacting the wastewater and ozone gas, there was. However, in this case, the compressed air of the high pressure by the air compressor penetrates the pores of the diffuser in the bubble state and proceeds to the waste water, reacting with the waste water, but the high pressure ozone gas by the air compressor rapidly passes through the waste water by the pressure difference. Since the reaction time is not enough, the reaction time is not enough, and the reaction between ozone and wastewater is not sufficiently achieved, and thus the wastewater is not sufficiently purified.

In addition, when ozone bubbles are generated using the diffuser, a blind spot where ozone does not reach is formed according to the size and size of the diffuser itself, so that ozone is not evenly supplied to the entire wastewater. There was a problem that it is difficult to sufficiently clean the waste water due to insufficient contact.

In addition, in the case of the ozone contact reaction mixer by mixing the piping line by the conventional ejector method, line mixing is adopted to supply and mix ozone to the wastewater flowing inside the pipe. Wastewater flowing to the pipe wall is attached to the pipe wall by its centrifugal force. Therefore, a space is formed at the center of the pipe, and ozone gas having a small specific gravity is eluted and moved to the space, so that a smooth mixing of waste water and ozone is achieved. There was a problem that the waste water was not sufficiently purified.

The present invention relates to an ozone contact reaction mixer for solving the above problems, by which the mixing method of the waste water and the ozone gas is different from the conventional method, so that the mixing is made smoothly, and the mixture of the ozone gas and the waste water is mixed. The purpose of the present invention is to sufficiently increase the purification efficiency of wastewater by sufficiently aging and reacting the contaminants ionized in the wastewater to sufficiently react with the ozone gas.

In order to achieve the above object, the present invention is an ozone contact reaction mixer for purifying waste water by contacting and mixing ozone with waste water, and mixing ozone introduced through an ozone suction pipe from the outside with waste water introduced from the waste water inlet pipe. And a ripening / reaction section for oxidizing contaminants contained in the wastewater while the ozone / wastewater mixed solution mixed by the mixing section collides with the curvature formed in the flow path, and from the mixed solution aged and reacted by the aging / reaction section. It consists of a separate discharge unit for separating the discharged waste ozone gas and purified water to be discharged naturally, the mixing unit to make the inlet of the ozone suction tube in a vacuum state to introduce ozone by the pressure difference with the outside, and the impeller A casing surrounding the outside of the nozzle, in which the liquid mixture of the ozone / wastewater is ejected by a centrifugal force from an impeller Relates to an ozone contact the reaction mixture, it characterized in that the impeller further comprises a casing part including a guide for the guide in an oblique direction to the discharge casing to the outside.

In the present invention, preferably, the mixing portion surrounds the outer circumference of the impeller casing in a state where a plurality of gears are engaged with each other, and accommodates the ozone / waste water mixture liquid discharged by the guide portion between the teeth of the gear, It relates to an ozone contact reaction mixer characterized by further comprising a gear portion for impinging and mixing the mixed liquid.

In addition, the present invention more preferably relates to an ozone contact reaction mixer, characterized in that at least one of the plurality of gears constituting the gear unit is driven by applying power.

Further, in the present invention, more preferably, the aging and reaction portion is composed of a waterway blocking frame provided at the lower portion and a waterway protection frame supported at the upper portion, wherein the waterway blocking frame and the waterway protection frame have a film formed therein. It is related to the ozone-contact reaction mixer, which is coupled to cross each other, and forms a flow path of the curved ozone-waste water mixture.

Further, in the present invention, more preferably, the separating and discharging portion is formed from a disk-shaped vortex membrane frame in which a discharge pipe for introducing the mixed liquid discharged from the aging and reaction portion into the separating and discharging portion is formed at the center thereof, and from the ripening and reaction mixture. It relates to an ozone contact reaction mixer characterized in that it further comprises a barrier membrane for separating the naturally occurring waste ozone gas from the purified water to flow out.

Further, in the present invention, the ozone contact reaction mixer is more preferably characterized in that two or more stages of the aging and reaction portions are laminated.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the present invention will be described in detail.

1 is a cross-sectional view showing a schematic configuration of an ozone contact reaction mixer according to an embodiment of the present invention. As shown, the ozone-contact reaction mixer has a four-stage structure in which the main body is composed of a stainless steel mixing section 300, a first aging and reaction section 310, a second aging and reaction section 320, and separation. Consists of the discharge portion 330, each end is inserted into the packing between the flange (27, 28, 29) and the flange of each end, is fastened to each other by a bolt and a nut is hermetically coupled to the outside.

In addition, the mixing part 300 includes an impeller 50, an impeller casing 70, and a gear part 220 in which a plurality of gears are engaged with each other on an outer circumference of the impeller 50 and the impeller casing 70. The aging / reaction parts 310 and 320 are cylindrical waterway blocking frames 90 and 110 installed at the lower portion thereof, and the cylindrical waterway protection frames 100 and 120 have four supports 104 and 124 disposed thereon. It is supported by and formed.

In addition, the separation discharge unit 330 is composed of a vortex membrane frame 130 and the solution gas separation frame 10, the motor 40 is mounted on the ozone discharger body by the motor base 230, the pulley of the motor shaft The impeller is rotated by a belt connected between 210 and the pulley of the impeller bearing casing shaft 180.

The internal structure of the bearing casing 180 is inserted in the impeller shaft to prevent leakage of the solution, the lower part of the secondary seal with a mechanical seal to block the leakage after mounting the bearing is difficult to rotate the shaft There was no. In addition, in this embodiment, the impeller and the shaft were configured to fasten the key groove.

In addition, a cleaning device valve 200 is provided below the mixing unit 300 to remove the mixed solution when the ozone contact mixing reactor is not driven.

Hereinafter, the operation of the ozone contact reaction mixer will be described in detail.

When wastewater flows in the upper part while the impeller 50 is rotated by the operation of the motor 40, a vacuum is formed at the lower part of the impeller 50, and thus, through the ozone suction pipe 80 connected to the ozone generator. Ozone gas is introduced.

The ozone suction pipe (80) is fastened by a union joint (190), and installs a check valve (190) in the middle to prevent the reverse flow of ozone.

4 is a perspective view and a cross-sectional view of the impeller 50. As shown, in the present embodiment, the length of the upper blade of the impeller 50 is slightly longer than the lower blade, but may be arbitrarily changed as necessary. When the waste water falls to the upper end of the impeller D through the wastewater inlet 20 in the rotating state of the impeller 50, a vacuum is formed in the lower part of the impeller 50, and thus ozone gas is lowered in the lower part of the impeller 50. It flows in through the ozone suction pipe 80 of (B), and the ozone gas and the wastewater in the lower portion (B) is in primary contact.

Thereafter, the primary mixed liquid of ozone gas and waste water by centrifugal force generated by the rotation of the impeller 50 is shown in FIG. 2 in a perspective view and a cross-sectional view of the impeller casing 70 containing the impeller 50. By having a hole of a row, and having a guide portion 71 formed at an oblique angle with the jet direction of the mixed liquid by the centrifugal force in the impeller, the mixed liquid ejected by the impeller is guided in a direction oblique to the direction of the centrifugal force by the impeller Discharge at an angle to the outside of the rotating impeller casing.

The ozone-waste water mixture liquid, which is guided by the guide unit 71 and formed at an angle with the direction of the centrifugal force formed by the impeller, is ejected and discharged, as illustrated in detail by FIGS. 3A to 3C. The gears 221 collide with the teeth of the gears 221, and the plurality of gears 221 meshing with each other by the collision and surrounding the outer circumference of the impeller 70 are rotated.

As the plurality of gears 221 rotate as described above, the secondary liquid is mixed between the teeth of the gears that rotate and mesh with each other by rotating the mixed liquid of ozone and wastewater injected obliquely from the impeller through the guide part 71. In addition, a mixture of ozone and wastewater is formed which is more perfectly mixed.

In the above description, the plurality of gears 221 are non-powered and may be rotated by collision with the teeth of the ozone / wastewater mixture liquid jetted and discharged by the guide unit 71, but the plurality of gears engaged with each other The shaft 222 of any one of the gears 221 may be rotated by applying power.

The specific operation described above can be more clearly understood by FIG. 3C, which illustrates a state in which the impeller 50, the impeller casing 70, and the gear unit 220 are assembled.

It is obvious that the power and the non-power selection of the gear can be appropriately selected in consideration of the use environment and cost of the present invention.

In addition, in the present embodiment, by lowering the height of the upper feather 51 of the impeller 50 to reduce the resistance when dispersing the wastewater as much as possible, the height of the lower feather 52 to increase the height of the impeller 50 when rotating Although it is intended to increase the vacuum efficiency, it is obvious that the design of such a feather can be applied in various modifications from the viewpoint of those skilled in the art.

The secondary mixture is discharged to the outside of the impeller casing 70 to be made by the gear unit 220, and the secondary mixed mixture passes through the gear unit 221 and then stays at the outside for a first time to ripen. Reaction and the ionized contaminants in the wastewater are oxidized by ozone.

The mixed liquid which has primaryly aged and reacted through the gear portion 221 and then outwardly moves to the upper portion of the mixed portion 300 as shown by an arrow in the mixed liquid flow path of FIG. Cylindrical channel flowed into the central inflow path 94 formed by the cylindrical membrane 92 of the cylindrical channel blocking frame 90 of the reaction unit 310, and then supported through the support 104 in the first aging and reaction unit The upper surface 101 of the protective frame 100 is hit and dispersed, and the pressure is greatly reduced, and the ionized contaminants of the mixed solution undergo secondary aging and reaction with ozone gas to oxidize.

Subsequently, the mixed liquid moves through the circular flow path formed by the cylindrical membrane 102 of the channel protection frame 100 and the cylindrical membrane 92 of the channel blocking frame 90 to the lower surface 91 of the channel blocking frame 90. Colliding and dispersing, and the pressure is greatly reduced to cause aging and reaction, and then passes through the flow path between the cylindrical membrane 93 of the channel blocking frame 90 and the cylindrical membrane 102 of the channel protection frame 100, The passage of the cylindrical membrane 93 and the cylindrical membrane 103 causes a sequential aging and reaction as described above.

As described above, the ozone-waste water mixed liquid is dispersed by colliding with many bends in the flow path formed by the cylindrical membrane formed in the cylindrical waterway protection frame 100 and the cylindrical waterway blocking frame 90 interlocking with each other, and the pressure drops. Ozone and ionized contaminants in the wastewater react easily and mature and react.

The flow of the mixed liquid in the second aging / reaction unit 320 having the same configuration as that of the first aging / reaction unit 310, and the process of aging / reaction are the same as those of the first aging / reaction unit, and thus will be omitted.

The mixed liquid having passed through the second aging / reaction unit 320 is a mixed liquid of purified purified water and waste ozone gas, and the central inlet of the vortex membrane frame 130 installed inside the separation discharge unit 330 shown in FIG. As shown by the arrow of FIG. 1 through the tube 131, the vortex is completely removed between the vortex membrane frame 130 shown in FIG. 7 and the solution gas separation frame 10 shown in FIG. The purified water is discharged through the discharge pipe 30, and the waste ozone gas is eluted naturally from the mixed liquid and discharged through the gas ejection valve 160 through the solution gas separation frame 10.

A pressure gauge 150 for measuring the pressure of the exhaust gas is connected to the gas ejection valve 160 by the T-type socket 140.

In addition, the inside of the discharge pipe of the waste ozone gas according to the present invention was filled with activated carbon to facilitate the adsorption of waste ozone gas from a mixture of purified water and waste ozone gas.

According to the present invention having a completely different configuration from the conventional ozone immersion reaction mixer as described above, since the ozone gas is not introduced into the ozone contact reaction mixer by the pressure difference due to the rotation of the impeller, the waste water is introduced. Purification efficiency can be maximized by sufficient mixing and aging and reaction time of ozone gas.

In addition, according to the present invention, it is possible to maximize the efficiency of the wastewater purification by lengthening the mixing, aging and reaction paths of the wastewater and ozone gas.

In addition, according to the present invention, it is possible to facilitate the aging and reaction of the wastewater and ozone gas by forming a bent flow path between the waterway protection frame and the waterway blocking frame of the aging and reaction portion to maximize the purification efficiency of the wastewater.

Further, according to the present invention, the waste water and ozone gas induced by the guide portion by the centrifugal force of the impeller collide and mix between the teeth of the gear portion, thereby maximizing the mixing and contact of the waste water and ozone gas, thus purifying the waste water. The efficiency can be maximized.

Claims (6)

Ozone contact reaction mixer which purifies wastewater by contacting and mixing ozone with wastewater, A mixing unit for mixing ozone introduced through the ozone suction pipe from the outside with wastewater introduced from the waste water inlet pipe, A aging / reaction part for oxidizing contaminants contained in the waste water while the ozone / waste water mixed solution mixed by the mixing part collides with the bending formed in the flow path and is dispersed; It consists of a separate discharge part for separating and discharge the waste ozone gas and purified water naturally eluted from the mixed solution aged and reacted by the aging reaction section, The mixing unit makes the inlet of the ozone suction pipe into a vacuum state, the impeller for introducing ozone by the pressure difference with the outside; A casing surrounding the outside of the impeller, the side of which further comprises an impeller casing including a guide portion for guiding the ozone / wastewater mixed solution in an oblique direction to the ejection direction due to centrifugal force from the impeller and discharging it out of the casing. Ozone contact reaction mixer, characterized in that. The method of claim 1, wherein the mixing unit, And a gear portion surrounding the outer periphery of the impeller casing in a state where a plurality of gears are engaged with each other and accommodating the mixed liquid discharged by the guide portion between the teeth of the gear to collide and mix the mixed liquid. Ozone contact reaction mixer. The ozone contact reaction mixer according to claim 2, wherein at least one of the plurality of gears constituting the gear unit is driven by applying power. The said aging / reaction part is comprised from the channel blocking frame provided in the lower part, and the channel protection frame supported in the upper part, The said channel blocking frame and the said channel protection frame are the same. An ozone contact reaction mixer, wherein the membranes formed therein are combined to cross each other to form a flow path of a curved ozone-waste water mixture. The method of claim 1, wherein the separation discharge portion, A disk-shaped vortex membrane frame in which a discharge pipe for introducing the mixed liquid discharged from the aging / reaction part into the separation discharge part is formed at the center thereof; An ozone-contacting reaction mixer, characterized in that it further comprises a barrier membrane which separates the waste ozone gas eluted naturally from the aging / reaction mixture from the purified water and discharges it upwards. The ozone-contact reaction mixer according to any one of claims 1 to 3, wherein the aging / reaction unit is laminated in two or more stages.

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