KR101581236B1 - Dust Collector using Ozon Water - Google Patents

Abstract

The present invention relates to an air purification apparatus using an ozonated water generator, and more particularly, to an air purification apparatus for purifying air containing contaminants containing odor components, Dissociated gas ozone is generated by mixing the gaseous ozone with the operating water to generate liquid ozone water, and the gaseous ozone not yet dissolved is separated through the gas-liquid separator, And the gas phase ozone is used for purifying ozone water containing contaminants flowing down through the metal filter.
According to the present invention, it is possible to make ozone by using oxygen in the general atmosphere, so that the ozone is superior in its efficiency and can be relatively miniaturized, and gas ozone and ozone water are separately used in a purifying process There is an advantage that the purification efficiency is extremely high.
In addition, there is no fear of generation of odor by gas ozone or NOx, there is no need to add a neutralizing agent due to acidification of operating water, and it is extremely easy to manage / adjust ozone concentration of ozone water.
On the other hand, residual moisture does not reach the activated carbon filter, and there is no fear of generation of germs and mold.

Description

TECHNICAL FIELD [0001] The present invention relates to an air purifier using an ultraviolet ozone generator and an ozonated water generator,

The present invention relates to an air purification apparatus using an ozonated water generator, and more particularly, to an air purification apparatus for purifying air containing contaminants containing odor components, Dissociated gas ozone is generated by mixing the gaseous ozone with the operating water to generate liquid ozone water, and the gaseous ozone not yet dissolved is separated through the gas-liquid separator, And the gas phase ozone is used for purifying ozone water containing contaminants flowing down through the metal filter.

Generally, air containing contaminants containing odor components is generated in many places in indoor spaces such as food preparation facilities, nursing homes, and hospitals. In the indoor space in which air containing pollutants containing odor components is generated, it is essentially necessary to discharge or purify air. In the past, only an exhaust device that discharges pollutant-containing air to the outside is used come.

However, such a simple exhaust system has the problem that the air containing the harmful pollutants is directly discharged to the outside air, thereby seriously affecting environmental pollution. In addition, there has been a problem in that simple exhaust in the indoor space where cooling or heating is performed deteriorates cooling / heating efficiency.

In order to solve the problems of the conventional simple exhaust system, various embodiments relating to a purifier for purifying air containing pollutants have been proposed and implemented. In one embodiment, as shown in FIG. 1, There was an air purification device used.

Such conventional air purifying apparatus using ozone uses oxidizing power of active oxygen (O) generated by decomposition of ozone to oxidize and oxidize active oxygen to contaminants or odor-causing bacteria or air in the air, It uses the principle of sterilizing action.

Conventional air purifying apparatuses using ozone for the purpose of generating ozone, as shown in FIG. 1, use the spark by electric discharge in the air, / Coupled to generate gaseous ozone.

However, in the process of generating gas phase ozone using such an electric discharge, there is a problem that the gas phase ozone peculiarly has an odor, and a chemical reaction also occurs with respect to nitrogen (N) contained in the air by electric discharge, There is a problem that NOx compounds that generate various kinds of odors are generated as represented by the general formula (2).

On the other hand, in order to smoothly deodorize / sterilize the gas ozone, it is preferable that the humidity in the air is about 70% or more. In the past, the mist of the operating water is sprayed to the gas phase ozone, And a method of generating ozone water by allowing gaseous ozone to dissolve has been used. However, in the conventional method of generating ozone water, since the method of spraying and dissolving the operating water into the gaseous ozone is used, the dissolved concentration thereof is extremely low, and ozone is mixed in the ozone water in the form of a bubble having a relatively large size And there is a problem that the efficacy is extremely low.

In addition, as described above, since the NOx compounds generated together with the gas phase ozone generated by the electric discharge are dissolved together with the working water and nitric acid is formed, the acidity of the operating water is increased, There is a problem that it is necessary.

Korean Patent No. 10-0510620

The present invention solves the above-described problems of the prior art, and it is possible to produce an ozone water having an extremely excellent effect by generating gas ozone by dissociating oxygen in the air by using ultraviolet rays by receiving air in the atmosphere And an object of the present invention is to provide an air purification apparatus using an ozonated water generator which has extremely high purification efficiency by using gas ozone and ozonated water separately in a purifying process through a gas-liquid separator.

In addition, there is no fear of generation of odor due to gas ozone or NOx, and there is no need to input a neutralizing agent due to acidification of operating water, and an air purification apparatus using an ozonated water generator which is extremely easy to control / The problem is to provide.

On the other hand, an object of the present invention is to provide an air purification apparatus using an ozonated water generator in which residual moisture does not reach the activated carbon filter, thereby preventing generation of germs and mold.

According to an aspect of the present invention,

1. An air purification apparatus for purifying air containing odor components, comprising:

A main body 110 formed with a suction port 111 through which air containing a pollutant containing a malodorous component is introduced at one side and an exhaust port 112 through which purified air is discharged at the other side;

An ozone generator 130 for dissociating oxygen in the air using at least one of air in the air and ultraviolet rays to generate gaseous ozone;

An ozonated water generator 140 for mixing the ozone generated in the ozonizer 130 with operating water supplied through a water supply source 131 to generate liquid ozonated water;

A gas-liquid separator 170 for temporarily storing the liquid ozonated water generated in the ozonated water generator 140 to separate gas-phase ozone not yet dissolved;

And a first metal filter 151 installed in the main body 110 on the side of the suction port 111 to allow the ozonated water supplied from the gas-liquid separator 170 to flow down, 150);

A water collection outlet 114 installed at a lower portion of the main body 110 below the metal filter unit 150 to collect and discharge the ozonated water containing pollutants;

A filter unit 160 installed inside the body 110 on the side of the exhaust port 112 and including at least one activated carbon filter 161 and 162 and a dustproof filter 163;

The gas ozone separated from the gas-liquid separator 170 and supplied through the gas ozone supply pipe 181 is temporarily stored in the ozonated water while temporarily storing the ozone water containing the pollutant discharged from the water collection outlet 114 An ozonated water purification unit 180 for bubbling and purifying contaminants;

An exhaust blower 190 installed at the exhaust port 112; And a control unit.

In addition, the ozonated water generator 140 includes:

A first inlet 141 for drawing the first working fluid to one side and a nozzle 142 at the other side, a second working fluid being drawn in, a nozzle 142 being installed on one side, and a diffuser And an ejection chamber 145 including a suction chamber 144 having a suction chamber 143 formed therein,

Wherein the first working fluid is either the working water or the gaseous ozone,

And the second working fluid is either the gas ozone or the working water as opposed to the first working fluid.

In addition, the ozonated water purification unit 180 includes:

An ozone discharge pipe 183 for discharging ozone gas on the surface of the ozone water through the bubbling process to the metal filter unit 150 inside the main body 110;

An ozonated water purifying filter 185 for purifying the ozonated water;

An operation water circulation pump (186) circulating the purified ozone water through the operation water and supplying it to the water supply source (131); And further comprising:

In addition, the metal filter unit 150 may further include at least one second metal filter 152,

The ozone water purifying filter 185,

And further comprises at least one of a mister filter, a pollutant-containing water cleaning filter or an activated carbon filter for adsorbing and purifying pollutants.

An external water supply source (132) connected to the water supply source (131) and replenishing the operation water insufficient during operation;

An ozone water discharge pipe (154) installed in front of the first metal filter (151) and allowing the ozonated water to flow in a curtain shape through an ozonated water supply pipe (153) connected to the ozonated water generator (140); And further comprising:

In the metal filter unit 150, a plurality of through-holes 11 in the form of a mesh grid through which the fluid can pass are formed so that the introduced fluid is deflected at an angle of 30 to 60 degrees, And a dust collecting screen plate (10) configured to pass through the filter screen (S).

The dust screen plates 10 may be arranged to have a deflection direction of 85 ° to 95 °, 175 ° to 185 ° or 265 ° to 275 ° with respect to the deflection direction of the previously installed dust screen plate 10 Is installed.

Further, the plurality of dust collection screen plates 10 are characterized by having a space portion between their installation positions.

The sensor unit 195 includes at least one sensor installed in the main body 110 and includes an ozone concentration sensor. The ozone sensor 130 may detect the concentration of ozone in the sensor unit 195, And a main controller 196 for performing a function of adding or stopping the operation amount of the main body.

A sludge discharging hole 184 opened and closed at the lower side of the ozonated water purifying unit 180 to discharge pollutant sludge accumulated in the ozonated water purifying unit 180; And further comprising:

In addition, the ozonated water purification unit 180 includes:

A level adjustment partition wall 187 provided on the bottom of the ozonated water purification unit 180;

And an inclined surface 188a is formed from the upper surface of the ozonated water purifying unit 180 so that the ozonated water containing contaminants introduced from the water collecting outlet 114 is induced and burned. A partition wall plate 188 extending below the extended surface a of the bottom surface of the ozonated water purifier unit 180;

And a sedimenting unit 189 further disposed below the bottom of the ozonated water purifying unit 180 below the partition plate 188 to deposit a high boiling point material H,

The sludge discharging means 184 is installed in the sedimenting unit 189,

The ozonated water purifying unit 180 may be configured to discharge the low specific gravity material L suspended in the space between the extended partition 188b and the ozonated water purification unit 180, A low specific gravity material discharging means (191) installed on one side surface;

And a low specific gravity sensor (192) for sensing when the low specific gravity material (L) is trapped and floated over a predetermined amount,

The main control unit 196 activates the low specific gravity material discharging means 191 when the low specific gravity material detecting sensor 192 detects that the low specific gravity material L is trapped and accumulated by a predetermined amount or more, And discharging the non-specific-gravity material (L).

The ozonated water supplied from the gas-liquid separator 170 is uniformly sprayed on the front surface of the metal filter unit 150 in the form of fine droplets, 155);

A spray diffusion chamber 156 further formed on an upper surface of the metal filter unit 150 of the main body 110;

The ozonated water supplied from the gas-liquid separator 170 is supplied to the upper part of the metal filter unit 150, An upper ozone water jetting nozzle 157 uniformly jetting in the form of fine droplets; And further comprising:

An induction partition 158 is installed in the body 110 between the metal filter unit 150 and the filter unit 160 so as to open at the lower part thereof.

A partition wall 159 disposed inside the body 110 so as to open at the rear of the induction partition wall 158;

A plurality of liquid collecting holes 159b are formed on the front surface of the separating partition wall 159 so as to be spaced apart from each other in the vertical direction and connected to the separating partition wall 159, Barrier ribs 159a;

And further comprising:

Also, an ozone leakage sensor (195a) installed at one or more of the ozone generator (130) or the ozonated water generator (140); Further comprising:

The main controller 196 further performs a function of stopping the operation of the ozone generator 130 when ozone leakage is detected in the ozone leak sensor 195a.

The main controller 196 further has a function of increasing or stopping the operation amount of the ozone generator 130 according to the concentration of ozone measured by the sensor unit 195.

According to the present invention, it is possible to make ozone by using oxygen in the general atmosphere, so that the ozone is superior in its efficiency and can be relatively miniaturized, and gas ozone and ozone water are separately used in a purifying process There is an advantage that the purification efficiency is extremely high.

In addition, there is no fear of generation of odor by gas ozone or NOx, there is no need to add a neutralizing agent due to acidification of operating water, and it is extremely easy to manage / adjust ozone concentration of ozone water.

On the other hand, residual moisture does not reach the activated carbon filter, and there is no fear of generation of germs and mold.

In addition, there is an advantage that contaminants contained in the ozonated water containing contaminants can be efficiently treated in the ozonated water purification unit by separating them into a low specific gravity material and a high gravity material.

In addition, it is possible to efficiently flow ozone water to the entire metal filter unit through the front ozone water injection nozzle and the upper ozonated water injection nozzle, and even when the flow rate of the gas is increased by processing a relatively large amount of flow in order to increase the purification efficiency per unit time It is possible to efficiently collect and remove droplets that can pass through the metal filter unit by a high flow rate.

On the other hand, there is an advantage that the concentration of the ozone remaining after the reaction is detected according to the concentration of the pollutant to be purified, thereby controlling the amount of generated ozone water, thereby preventing the unreacted ozone gas from being discharged.

1 is a schematic diagram showing the entire configuration of an air purification apparatus using an ozonated water generator according to an embodiment of the present invention;
2 is a schematic diagram showing the structure of an ozonated water generator of an air purification apparatus using an ozonated water generator according to an embodiment of the present invention;
3 is a perspective view showing a configuration of a metal filter unit of an air purification apparatus using an ozonated water generator according to an embodiment of the present invention;
4 is a view showing a configuration of a metal filter constituting a metal filter unit of an air purifier using an ozonated water generator according to an embodiment of the second embodiment of the present invention.
5 is a cross-sectional view taken along the line III-III in Fig. 4; Fig.
6 is a sectional view taken along the line IV-IV in Fig. 4; Fig.
7 is a view showing a configuration of a metal filter constituting a metal filter unit of an air purification apparatus using an ozonated water generator according to an embodiment of the second embodiment of the present invention.
8 is a perspective view showing a structure of a metal filter unit using a metal filter in an air purifier using an ozonated water generator according to a second embodiment of the present invention;
9 is a schematic diagram schematically showing the flow of airflow passing through each metal filter constituting the metal filter unit in the air purifier using the ozonated water generator according to the second embodiment of the present invention.
10 is a schematic diagram showing another embodiment of an ozonated water purification unit of an air purification apparatus using an ozonated water generator according to an embodiment of the present invention.
11 is a schematic view showing another embodiment for supplying ozone water to a metal filter unit of an air purifier using an ozonated water generator according to an embodiment of the present invention and an induction partition wall and a partition wall for liquid droplet separation.
12 is a schematic diagram showing another configuration of an ozonated water purification filter of an air purification apparatus using an ozonated water generator according to an embodiment of the present invention;

Hereinafter, an air purifier using an ozonated water generator according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that, in the drawings, the same components or parts are denoted by the same reference numerals whenever possible. In describing the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

1, an air purifier using the ozonated water generator of the present invention includes a main body 110, an ozonizer 130, an ozonated water generator 140, a metal filter unit 150, a gas-liquid separator 170, And an ozonated water purification unit 180.

First, the main body 110 will be described. As shown in FIG. 1, the main body 110 has a suction port 111 formed at one side for introducing air containing pollutants including odor components generated in an indoor space, and a pollutant is purified And an exhaust port 112 for discharging the air back into the indoor space. The air circulation means may be provided on the side of the intake port 111, the inside of the main body 110 or the side of the exhaust port 112 But it is preferable that the exhaust air blower 190 is further connected to the exhaust port 112 as shown in FIG. 1 for preventing pollution and stable operation of the air circulation means Do.

As shown in FIG. 1, a lower portion of the metal filter unit 150 is provided at a lower portion of the main body 110 to collect and discharge the ozonated water containing contaminants flowing from the metal filter unit 150, (114).

Next, the ozone generator 130 will be described. 1, the ozone generator 130 has a function of generating air ozone by decomposing oxygen in the air by receiving air in the air. Such an ozone generation process is generally used as a method of electrolysis in which ozone is generated by passing oxygen through a plasma discharge between two electrodes.

However, in a known ozone generator in which ozone is generated by a plasma (corona) discharge in a general atmospheric air, a by-product such as nitrogen oxide is generated when a plasma (corona) is discharged. Therefore, It is necessary to provide a means, resulting in an increase in size and cost of the device.

Therefore, it is preferable that the ozone generator 130 has a configuration using ultraviolet rays that can generate gas phase ozone by dissociating only oxygen without projecting ultraviolet rays of a specific wavelength to dissociate nitrogen in the air. As an embodiment of the ozone generator 130 using the ultraviolet ray projection, an ultraviolet lamp may be installed in a space shielded to some extent so that ultraviolet rays are not emitted to the outside. In this case, it is preferable that the ultraviolet lamp is a light source that mainly emits light having wavelengths of 185 nm and 254 nm so as to selectively dissociate only oxygen to generate ozone by selectively acting on oxygen. As described above, since the ultraviolet light source is used, it is inexpensive, light in weight, and simple in maintenance, so that it is possible to reduce cost, lightness, maintenance, and light source exchange as a deodorizing device.

The technique for constructing and operating the ozonizer 130 having the above-described functions is a well-known technology in the technical field of the present invention, and a detailed description thereof will be omitted.

Next, the water supply source 131 will be described. The water supply source 131 has a function of storing and supplying the operating water necessary for the operation as shown in Fig. As shown in FIG. 1, it is preferable that the purified water supplied through the ozonated water purification unit 180 is supplied again to the water supply source 131, so that the operation water is not frequently supplied additionally Do. In this case, as shown in FIG. 1, it is preferable that the water supply source 131 further includes an internal water supply tank 132b. The external water supply source 132 may be further connected to the water supply source 131 as shown in FIG. 1 so as to supplement the operation water that is insufficient during operation.

Next, the ozonated water generator 140 will be described. 1, the ozonated water generator 140 has a function of generating liquid ozonated water by mixing the operating water supplied from the water supply source 131 and the gaseous ozone supplied from the ozone generator 130 . An embodiment of the ozonated water generator 140 having such a function can be a very various embodiment. In one embodiment, the ozonated water generator 140 includes an ejector 145 as shown in FIG. 2 .

The ejector 145 is a kind of pump that ejects water, steam, or air having a pressure from an ejection port to an outside at a high speed to send the surrounding fluid to another place. The ejector 145 has a simple structure, . In this case, the ozonated water generator 140 includes a first inlet 141 through which the first working fluid is drawn into one side and a nozzle 142 formed on the other side, And an ejector 145 including a suction chamber 144 provided on one side and a diffuser 143 on the other side, And the second working fluid is any one of the gaseous ozone or the working water as opposed to the first working fluid.

Next, the metal filter unit 150 will be described. As shown in FIG. 1, the metal filter unit 150 is installed inside the main body 110 on the suction port 111 side. As shown in FIG. 1, the metal filter unit 150 includes a first metal filter 151. The first metal filter 151 includes a first metal filter 151, As the ozone water supplied from the ozonated water generator 140 flows down, contaminants in the air including the contaminants passing through the metal filter unit 150 are trapped by the ozonated water and react with the ozonated water, The organic matter decomposition action occurs and is purified. In addition, the temperature of the air including pollutants is also lowered. In this case, the ozone water may be supplied to the first metal filter 151. In an embodiment of the present invention, the first metal filter 151, It is preferable to provide the ozone water supply pipe 153 on the upper side. In this way, the ozonated water supplied from the ozonated water generator 140 flows into the metal filter unit 150 so that the ozonated water flows down. Thus, the ozonated water droplets are scattered in the air to be supplied to the activated carbon filter in the filter unit 160 It is possible to prevent the droplets from accumulating and deteriorate the ozone purifying efficiency and the air purifying efficiency, thereby enabling more efficient purifying operation. The ozone water also has a function of controlling the temperature and humidity of the air containing contaminants.

As shown in FIG. 1, the metal filter unit 150 may further include at least one second metal filter 152, and may be mixed with the air passing through the first metal filter 151 It is preferable to collect additional pollutants while flowing away the water contained therein. In this case, the first metal filter 151 and the second metal filter 152 can be implemented in various embodiments. In one embodiment, the first metal filter 151 and the second metal filter 152 It is possible that the second metal filter 152 is formed by laminating a metal mesh material.

1 and 3, the ozonated water flows in a curtain shape through the ozonated water supply pipe 153 connected to the ozonated water generator 140, which is installed in front of the first metal filter 151 The ozone water discharge pipe 154 may be further provided to wash off large pollutants and the like so as to be able to remove contaminants more efficiently. Meanwhile, it is preferable that the ozone water flowing through the ozone water discharge pipe 154 has a curtain-wall shape by controlling the flow rate and the flow rate of the ozone water so that the ozone water does not generate droplets.

4 to 7, the metal filter unit 150 includes a mesh-shaped through-hole through which the fluid can pass, A dust collecting screen plate (10) is formed in which a fluid containing contaminants such as dust is introduced into the through hole (11) at an angle of 30 to 60 degrees so as to be deflected in one direction, And a metal filter screen (S) formed of at least one metal filter screen (S). In this case, the metal filter screen S is generally constructed by stacking about 5 to about 20 dust screen plates 10.

The larger the deflection angle of the fluid passing through the through hole 11 is, the smaller the pressure drop of the fluid passing through the through hole 11 becomes, but the dust collecting effect due to the impact is lowered. The collecting effect is better, but the deterioration of the wall of the passing fluid becomes worse. Therefore, the deflection angle is preferably in the range of 30 to 60 degrees, and most preferably 45 degrees as shown in Fig.

The shape and size of the through-hole 11 can be changed into a very wide variety of embodiments. In one embodiment, as shown in FIG. 4, The width A of the band constituting the through hole is 2.25 mm and the opening angle D of the through hole 11 is in the vicinity of 110 DEG .

The method of manufacturing the dust-collecting screen plate 10 such that a plurality of the through-holes 11 are arranged is also possible according to a very wide variety of embodiments. In one embodiment, as shown in FIGS. 4 and 7, As shown, it is preferable that a plurality of the through holes 11 are formed by press-working a metal material in the form of a plate.

In this case, the dust screening plates 10 are arranged at an angle of 85 ° to 95 °, 175 ° to 185 ° with respect to the deflection direction of the dust screening plate 10 previously installed, as shown in FIG. 4 or FIG. Or a deflection direction of 265 ° to 275 °. In this arrangement, it is possible to minimize the pressure drop of the fluid passing through each of the dust screen plates 10 and to maximize the dust collecting efficiency while maximizing the traveling path.

Further, the plurality of dust screening plates 10 may further include a space 12 between their mounting positions as shown in FIG. 8 so that the fluid once passed through one dust screening plate 10 It is preferable that the direction of the flow can be made uniform to some extent before it is introduced into the dust screening plate 10 arranged next. In this case, the spacing of the space portions 12 can be implemented in a very wide variety of embodiments, and it is generally sufficient to have an interval of 1 mm to 10 mm.

On the other hand, the contaminants or dust collected on the surface of the dust screen plate 10 are immediately washed away by the ozonated water supplied to the surface of the dust screen plate 10, so that no separate dust removing operation is required .

In order to allow the ozonated water to flow down to the metal filter unit 150, it is preferable that the ozonated water can be supplied through the entire metal filter unit 150.

11, the ozone water is supplied from the gas-liquid separator 170 to the front surface of the metal filter unit 150, and the ozone water supplied from the gas- A spray diffusion chamber 156 further formed on the upper surface of the metal filter unit 150 of the main body 110 and a discharge diffusion chamber 156 formed on the upper surface of the main filter 110, And the ozonated water supplied from the gas-liquid separator 170 is uniformly sprayed onto the upper portion of the metal filter unit 150 in the form of fine droplets, And an upper ozone water injection nozzle 157 for spraying the ozone water.

On the other hand, when the flow rate of the gas is increased by processing a relatively large flow rate to increase the purification efficiency per unit time, there is a possibility that droplets passing through the metal filter unit 150 may be generated at a high flow velocity, There is a fear that the operating efficiency of the battery is lowered. In order to prevent such a problem, as shown in FIG. 11, an induction partition (not shown) installed inside the body 110 between the metal filter unit 150 and the filter unit 160, And a partition wall 159 disposed at the rear of the induction partition wall 158 so as to open at an upper portion of the partition wall 159. The partition wall 159 is formed at the front of the partition wall 159, A liquid droplet collecting partition wall 159a having at least one liquid passage hole 159b formed at a portion connected to the separating partition wall 159 is provided so as to be disposed at one or more intervals in the vertical direction toward the front The droplet capable of passing through the metal filter unit can be efficiently trapped and removed by the droplet collecting partition wall 159a due to the fast flow rate even when the flow velocity of the gas is accelerated Preferable.

Next, the filter unit 160 will be described. 1, the filter unit 160 is installed inside the main body 110 on the side of the exhaust port 112, and includes at least one activated carbon filter 161, 162 and a dustproof filter 163 .

In this case, the filter unit 160 has a function of adsorbing deodorant and contaminants contained therein, and at the same time decomposing ozone contained in the air by using a carbon component contained in the activated carbon, So as to prevent ozone from being discharged to the outside.

It is preferable that the dustproof filter 163 is made of a material having sterilization effect in addition to simply collecting fine dust remaining in the air. Since the dust-proof filter having the sterilizing effect is widely known and practiced in the technical field of the present invention such as a hospital or the like, the detailed description will be omitted.

Next, the gas-liquid separator 170 will be described. 1, the gas-liquid separator 170 has a function to temporarily store the liquid ozone water generated in the ozonated water generator 140 and to separate gas-phase ozone that has not yet dissolved. The ozonated water generated in the ozonated water generator 140 by the gas-liquid separator 170 separates ozonated water in the liquid state and gaseous ozone not dissolved therein through the gas-liquid separator, Since ozone water containing pollutants flowing down through the metal filter can be used for purifying the air through the ozone water purifying unit 150, Thereby reducing the amount of gaseous ozone flowing into the main body 110 so that the ozone is hardly contained in the air passing through the filter unit 160 so that the ozone is hardly discharged into the room .

Meanwhile, when the air purifier 100 using the ozonated water generator of the present invention is operated, if the normal operation can not be performed for various reasons (for example, failure of the exhaust blower), the ozone gas There is a risk of leakage to the outside. In order to prevent such a situation, the air purifier 100 using the ozonated water generator of the present invention preferably includes at least one sensor 195 installed inside the main body 110 as shown in FIG. 1 . In this case, the sensor 195 may include at least one of various sensors such as a pressure sensor, a pollutant concentration sensor, or an ozone concentration sensor.

Meanwhile, in the present invention, a principle that ozone and contaminants cause various chemical reactions for the purification of pollutants is used. However, in the case of this purge function through chemical reaction, the amount of ozone participating in the reaction depends on the concentration of the contaminant reacting. That is, when the concentration of the pollutant is high, the amount of ozone participating in the reaction is increased. When the concentration of the pollutant is low, the amount of ozone participating in the reaction is decreased, do. In the extreme case, when there is no contaminant in the air to be inhaled, ozone contained in the supplied ozone water remains as unreacted residual ozone since there is no ozone participating in the reaction. In this case, There is a possibility that unreacted residual ozone exceeding decomposition ability and speed is released to the outside. In order to solve such a problem, in the present invention, the sensor unit 195 further comprises an ozone concentration sensor, and the operation amount of the ozone generator 130 is determined according to the concentration of ozone measured by the sensor unit 195 And a main controller 196 which has a function of adding or subtracting the main control signal from the main control unit. That is, the ozone concentration before, during, and after the passage of the metal filter unit 150 and the filter unit 160 is measured and the operation amount of the ozone generator 130 is adjusted according to the measured ozone concentration, It is preferable that the amount of ozone generated in the filter unit 130 is adjusted so as to be used in a chemical reaction for purifying most contaminants or at least through the filter unit 160 to be completely decomposed. The concentration of ozone remaining after the reaction is detected according to the concentration of the contaminants flowing into the ozone generator, thereby controlling the amount of generated ozone water, thereby preventing the unreacted ozone gas from being discharged.

In this case, the sensor unit 195 also measures the concentration of contaminants flowing into the sensor unit 195, and the main controller 196 refers to the concentration of the contaminant measured by the sensor unit 195, It is preferable to further have a function of adding or stopping the operation amount of the unreacted ozone gas so as to more accurately and efficiently prevent the unreacted ozone gas from being discharged.

1, the main controller 196 may further include an ozone leakage sensor 195a installed in at least one of the ozone generator 130 and the ozonated water generator 140, When the ozone leaking sensor 195a detects ozone leakage, the ozone generator 130 is stopped. If the ozone leaks due to an abnormal operation during operation, an emergency stop function Is preferably performed.

Next, the ozonated water purification unit 180 will be described. 1, the ozone water purifying unit 180 separates the ozone water containing the pollutants discharged from the water collecting and discharging outlet 114 for a predetermined time, separates from the gas-liquid separator 170, And bubbling the gaseous ozone supplied through the ozone generator 181 to the ozone water to purify the contaminants for a sufficient time. In this process, the gaseous ozone purifies the ozone water containing the contaminant, and a large amount of the gaseous ozone is dissolved in the ozone water. That is, the second function is to perform the function of mixing and dissolving the working water and the gas phase ozone. In this case, when the volume of the ozonated water purifying unit 180 is increased to some extent, the ozonated water is kept in the ozonated water purifying unit 180 for a sufficient time, The ozone is dissolved in the ozone water. On the other hand, some of the gaseous ozone that is not dissolved through the bubbling process and comes out above the water surface of the ozonized water is introduced into the metal filter unit (not shown) through the ozone discharge pipe 183 150) to be decomposed as shown in Formula (3). Therefore, it is possible to prevent ozone from being almost discharged into the room.

1, the ozone water purifying unit 180 is provided with an ozone water purifying filter 185 for purifying the ozone water, an operating water circulating unit 180 for circulating the purified ozone water through the operating water to the water supply source 131, It is preferred that the pump 186 is further configured to be connected. In this case, the ozone water supplied to the water supply source 131 through the working water circulation pump 186 is partially dissolved in the gas ozone, so that the efficiency of generating ozone water can be further increased.

In this case, the ozone water purifying filter 185 may further comprise at least one of a mist filter, a pollutant-containing water cleaning filter, or an activated carbon filter for adsorbing and purifying contaminants.

12, the ozone water purifying filter 185 may include a filter 185b including at least one of a mist filter, a contaminant-containing water cleaning filter, or an activated carbon filter for adsorbing and purifying contaminants And a gas phase ozone supply pipe 185a provided below the filter accommodating portion 185a and separated from the gas-liquid separator 170 and supplied through the gas ozone supply pipe 181, And an upper portion of the filter accommodating portion 185a is connected to the ozone exhaust pipe 185b so as to discharge the gas ozone having passed through the filters 185b and 185c, 183, respectively. In this case, the gaseous ozone discharged through the filter ozone discharge pipe 185d passes through the filters 185b and 185c as shown in FIG. 12, and purifies contaminants adsorbed on the filters 185b and 185c It is possible to do. 12, since the gas phase ozone is crushed into fine bubbles while passing through the filters 185b and 185c, the ozone water containing the contaminants is more efficiently purified, and at the same time, More parts are dissolved.

As shown in FIG. 1, the ozonated water purifying unit 180 is provided with a sludge discharging / discharging unit 160 disposed below the ozonated water purifying unit 180 so as to discharge contaminant sludge accumulated in the ozonated water purifying unit 180 It is preferable to further include the hole 184.

In this case, the pollutants contained in the ozonated water discharged from the water collecting outlet 114 may contain various pollutants. Among these pollutants, the dissolved pollutants dissolved in the ozonated water, There are also cost-zone contaminants in the mixed state as well as the substance, not dissolved in the ozonated water. The cost zone pollutants are classified into a low specific gravity material L which can be floated on the water surface of the ozonated water because the specific gravity is smaller than the ozonated water and a high specific gravity material H which has a specific gravity larger than that of the ozonated water, . If the cost zone pollutants including the low specific gravity material (L) or the high specific gravity material (H) can not be efficiently treated in advance, the purification by the bubbling operation in the ozonated water purifying unit (180) There arises a problem that the efficiency of purifying ozone water through the filter 185 may deteriorate.

10, the ozonated water purifying unit 180 includes a water level adjusting partition wall 187 provided on the bottom surface of the ozonated water purifying unit 180, The ozonated water purification unit 180 is installed to form an inclined surface 188a from the upper surface of the ozonated water purification unit 180 so that the ozonated water containing the contaminants is induced and burned. The lower end of the ozonated water purification unit 180 forms an extended partition wall 188b. And a partition plate 188 extending downwardly from the bottom surface of the bottom plate 188. 10, a sedimentation section 189 is formed under the bottom surface of the ozonated water purification unit 180 so as to deposit the high-boiling substance H thereon, as shown in FIG. .

10, when the ozonated water purification unit 180 further includes the water level adjustment partition 187, the partition plate 188 and the sedimentation unit 189, It is preferable to be provided on the above-mentioned sedimenting portion 189 as shown.

In this case, in order to discharge the low specific gravity material L floating on the water surface of the ozonated water W in the space between the extended partition wall 188b and the ozonated water purifying unit 180, And a low specific gravity material discharging means 191 disposed on one side of the bottom surface 180a. The main control unit 196 further includes a low specific gravity material detection sensor 192 for detecting when the low specific gravity material L is trapped and floated by a predetermined amount or more, 192 has a function of discharging the low specific gravity material L by operating the low specific gravity material discharging means 191 when it is detected that the low specific gravity material L is trapped by floating over a predetermined amount desirable.

The air purifier 100 using the ozonated water generator according to the present invention can be used for purifying various contaminants. One example of the air purifier 100 is isopropyl alcohol (IPA), which may occur in a nursing facility such as a hospital or a semiconductor manufacturing facility, Isopropyl alcohol decomposition.

The isopropyl alcohol is an aliphatic saturated alcohol which is an isomer of propanol. It is a colorless, flammable liquid with a characteristic odor and is widely used as solvent and cleaning liquid. The isopropyl alcohol is decomposed into acetone and water through a chemical reaction represented by the following chemical formula 4 by the ozonated water.

In this case, it is known that acetone in the reaction products does not cause irritation symptoms to humans even after exposure to 500 ppm in air for 2 hours in general, and is not considered to be a carcinogenic or mutagenic chemical substance. , It is used for various consumer products such as processed foods from cosmetics and is generally regarded as a safe substance when the acetone concentration is in the range of 58 mg / L.

In the foregoing, optimal embodiments have been disclosed in the drawings and specification. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

W: ozone water L: low specific gravity material
H: high boiling matter
100: Air purifier using ozonated water generator
110:
111: intake port 112: exhaust port
114: water collecting outlet 115: shutter
130: ozone generator
131: water supply source 132a: external water supply source
132b: internal water supply tank
140: ozonated water generator
150: Metal filter unit
151: first metal filter 152: second metal filter
153: ozonated water supply pipe 154: ozone water discharge pipe
155: forward ozone water injection nozzle 156: injection diffusion chamber
157: Upper ozone water injection nozzle
158: Inductive bulkhead 159:
159a: droplet collecting bulkhead 159b: liquid passing hole
160: Filter unit
161: first activated carbon filter 162: second activated carbon filter
170: gas-liquid separator
180: ozonated water purification unit
181: Gas ozone supply pipe 182: Bubbling nozzle
183: ozone discharge pipe 184: sludge discharge means
185: ozone water purification filter 185a: filter accommodating portion
185d: filter ozone discharge pipe
186: circulation pump
187: Leveling partition wall 188:
189:
190: Exhaust blower
191: means for discharging low specific gravity material 192: means for detecting low specific gravity material
195: sensor 195a: ozone leak detection sensor
196: Main control unit

Claims (14)

1. An air purification apparatus for purifying air containing odor components, comprising:
A main body 110 formed with a suction port 111 through which air containing a pollutant containing a malodorous component is introduced at one side and an exhaust port 112 through which purified air is discharged at the other side;
An ozone generator 130 that receives air in the air and dissociates oxygen in the air using ultraviolet rays to generate gaseous ozone;
An ozonated water generator 140 for mixing the ozone generated in the ozonizer 130 with operating water supplied through a water supply source 131 including an internal water supply tank 132b to generate liquid ozonated water;
A gas-liquid separator 170 for temporarily storing the liquid ozonated water generated in the ozonated water generator 140 to separate gas-phase ozone not yet dissolved;
And a first metal filter 151 installed in the main body 110 on the side of the suction port 111 to allow the ozonated water supplied from the gas-liquid separator 170 to flow down, 150);
A water collection outlet 114 installed at a lower portion of the main body 110 below the metal filter unit 150 to collect and discharge the ozonated water containing pollutants;
A filter unit 160 installed inside the body 110 on the side of the exhaust port 112 and including at least one activated carbon filter 161 and 162 and a dustproof filter 163;
The gas ozone separated from the gas-liquid separator 170 and supplied through the gas ozone supply pipe 181 is temporarily stored in the ozonated water while temporarily storing the ozone water containing the pollutant discharged from the water collection outlet 114 An ozonated water purification unit 180 for bubbling and purifying contaminants;
An exhaust blower 190 installed at the exhaust port 112; (100) using the ozonated water generator.
The method according to claim 1,
The ozonated water generator (140)
A first inlet 141 for drawing the first working fluid to one side and a nozzle 142 at the other side, a second working fluid being drawn in, a nozzle 142 being installed on one side, and a diffuser And an ejection chamber 145 including a suction chamber 144 having a suction chamber 143 formed therein,
Wherein the first working fluid is either the working water or the gaseous ozone,
Wherein the second working fluid is either gas-phase ozone or operating water as opposed to the first working fluid.
The method of claim 2,
The ozonated water purification unit 180 includes:
And an ozone discharge pipe (183) for discharging gaseous ozone flowing over the ozone water surface through the bubbling process to the metal filter unit (150) inside the main body (110)
An ozonated water purifying filter 185 for purifying the ozonated water;
An operation water circulation pump (186) circulating the purified ozone water through the operation water and supplying it to the water supply source (131); The ozonized water generating apparatus according to claim 1, further comprising:
The method of claim 3,
The metal filter unit 150 further includes at least one second metal filter 152,
The ozone water purifying filter 185,
(100) using the ozonated water generator, characterized by further comprising at least one of a mister filter, a contaminant water cleaning filter or an activated carbon filter for adsorbing and purifying contaminants.
The method of claim 4,
An external water supply source (132) connected to the water supply source (131) and replenishing the operation water insufficient during operation;
An ozone water discharge pipe (154) installed in front of the first metal filter (151) and allowing the ozonated water to flow in a curtain shape through an ozonated water supply pipe (153) connected to the ozonated water generator (140); The ozonated water generating apparatus according to claim 1, further comprising:
The method according to any one of claims 1 to 5,
The metal filter unit (150)
A plurality of through holes 11 in the form of a mesh grid through which fluids can pass are formed so that the inflow fluid can be deflected in one direction at an angle of 30 to 60 degrees to pass through the through holes 11 And a metal filter screen (S) comprising at least one dust collecting screen plate (10).
The method according to claim 6,
The dust screen plates 10 are installed to have a deflection direction of 85 ° to 95 °, 175 ° to 185 ° or 265 ° to 275 ° with respect to the deflection direction of the previously installed dust screen plate 10 ,
Wherein the plurality of dust collecting screen plates (10) have a space between their installed positions.
The method of claim 7,
A sensor unit 195 including at least one ozone concentration sensor installed inside the body 110;
A main controller 196 for controlling the operation amount of the ozone generator 130 according to the concentration of ozone measured by the sensor unit 195; The ozonized water generating apparatus according to claim 1, further comprising:
The method of claim 8,
A sludge discharging hole 184 which is openably and downwardly installed on the lower side of the ozonated water purifying unit 180 so as to discharge pollutant sludge accumulated in the ozonated water purifying unit 180; The ozonated water generating apparatus according to claim 1, further comprising:
The method of claim 3,
The ozone water purifying filter 185,
A filter accommodating portion 185a in which filters 185b and 185c configured to adsorb and purify contaminants further include at least one of a Mr filter, a contaminant water cleaning filter, or an activated carbon filter;
A filter ozone discharge pipe 185d provided below the filter accommodating portion 185a to discharge gas ozone separated from the gas-liquid separator 170 through the gas ozone supply pipe 181; Further comprising:
The upper portion of the filter accommodating portion 185a is further connected to the ozone discharge pipe 183 to discharge the gas ozone having passed through the filters 185b and 185c. (100).
The method according to claim 9,
A front ozone water injection nozzle 155 installed at the center of the inlet port 111 for uniformly spraying the ozonated water supplied from the gas-liquid separator 170 on the entire surface of the metal filter unit 150 in the form of fine droplets, ;
A spray diffusion chamber 156 further formed on an upper surface of the metal filter unit 150 of the main body 110;
The ozonated water supplied from the gas-liquid separator 170 is supplied to the upper part of the metal filter unit 150, An upper ozone water jetting nozzle 157 uniformly jetting in the form of fine droplets; The ozonated water generating apparatus according to claim 1, further comprising:
The method according to claim 9,
An induction partition wall 158 installed inside the body 110 between the metal filter unit 150 and the filter unit 160 so as to be opened at a lower portion thereof;
A partition wall 159 disposed inside the body 110 so as to open at the rear of the induction partition wall 158;
A plurality of liquid collecting holes 159b are formed on the front surface of the separating partition wall 159 so as to be spaced apart from each other in the vertical direction and connected to the separating partition wall 159, Barrier ribs 159a;
The ozonated water generating apparatus according to claim 1, further comprising:
The method according to claim 9,
An ozone leakage sensor (195a) installed at one or more of the ozone generator (130) or the ozonated water generator (140); Further comprising:
The main controller 196 further performs a function of stopping the operation of the ozone generator 130 when ozone leakage is detected in the ozone leakage sensor 195a. 100).
The method according to claim 9,
A front ozone water injection nozzle 155 installed in the center of the inlet port 111 for uniformly spraying the ozonated water supplied from the gas-liquid separator 170 on the entire surface of the metal filter unit 150 in the form of fine droplets, ;
A spray diffusion chamber 156 further formed on an upper surface of the metal filter unit 150 of the main body 110;
The ozonated water supplied from the gas-liquid separator 170 is supplied to the upper part of the metal filter unit 150, An upper ozone water jetting nozzle 157 uniformly jetting in the form of fine droplets; And further comprising:

An induction partition wall 158 installed inside the body 110 between the metal filter unit 150 and the filter unit 160 so as to be opened at a lower portion thereof;
A partition wall 159 disposed inside the body 110 so as to open at the rear of the induction partition wall 158;
A plurality of liquid collecting holes 159b are formed on the front surface of the separating partition wall 159 so as to be spaced apart from each other in the vertical direction and connected to the separating partition wall 159, Barrier ribs 159a;
And further comprising:

A sensor unit 195 including at least one ozone concentration sensor installed inside the body 110;
A main controller 196 for controlling the operation amount of the ozone generator 130 according to the concentration of ozone measured by the sensor unit 195; The ozonized water generating apparatus according to claim 1, further comprising:

Images