KR20090132531A - Liquid treatment apparatus and method using the non contacting lamp and high pressure ozone - Google Patents

Abstract

PURPOSE: A water treatment apparatus using a contactless lamp and pressurized ozone and a water treatment method using the same are provided to increase degradability and sterilization efficiency included in treated water using OH radical having strong oxidizing potential. CONSTITUTION: A water treatment apparatus using a contactless lamp and pressurized ozone includes a lamp part discharge ultraviolet rays and dipping in a pressure tank(150) and a dissolved ozone processing part(170) processing the dissolved ozone which is contained in treated water(110). The lamp part comprises the followings: a housing(210) of which bottom part is opened; a ultraviolet ray lamp(220) generating the ultraviolet rays(280); a gas layer(230) protecting the ultraviolet ray lamp; a water level detector(250) maintaining a water level uniformly; a gas supply pipe(260) supplying the gas; a reflection plate(240) maximizing the ultraviolet irradiation intensity; and a gas shield formed between the ultra-violet ray lamp and the gas layer.

Description

Liquid treatment apparatus and method using the non contacting lamp and high pressure ozone}

The present invention relates to a water treatment apparatus and method using a non-contact lamp and a pressurized ozone, and more particularly, by placing a gas layer between the ultraviolet lamp and contaminated water to prevent the ultraviolet lamp and the protection device from directly contacting the water to be contaminated. It is equipped with a non-contact UV lamp to prevent contamination of the UV lamp by the material and a pressure tank to apply pressure, and water treatment is performed using OH radicals having strong oxidation power generated by the reaction of UV and ozone to decompose the pollutants. The present invention relates to a water treatment apparatus and method using a non-contact UV lamp and a pressurized ozone capable of increasing sterilization efficiency.

In general, sewage or sewage flowing into a sewage treatment plant or sewage treatment plant contains various contaminants such as dirt and bacteria. Chemicals, chlorine, ozone, ultraviolet rays, etc. are used to disinfect and sterilize bacteria contained in sewage or sewage. Advanced membrane treatment, activated carbon adsorption, electrodialysis, biofilm application technology, advanced oxidation treatment process (AOP), etc. Sewage effluent is recycled using water treatment technology.

The water treatment method using the Advanced Oxidation Process (AOP) uses oxidizing agents such as ozone and hydrogen peroxide, or irradiates ultraviolet rays to the oxidizing agent, which is a chemical species having strong sterilization and oxidizing power (OH radical, OH radical). It is a technology to oxidize and decompose organic substances and toxic substances, which are various pollutants in waste water, by producing as intermediate products. This is more economical and efficient than using ozone alone because it has more powerful oxidizing power such as chlorine, chlorine dioxide, and potassium permanganate. In addition, it is possible to decompose hardly decomposable substances such as synthetic detergents and pesticides that are not easily decomposed by a general treatment method, or to treat high concentrations of contaminants in a short time.

The development of new technology for wastewater treatment with better treatment efficiency is progressing due to the increase of environmental pollution, the emergence of new materials that cannot be treated with existing treatment methods, and the increase of the amount of these hardly decomposable substances into the wastewater. There is an increasing demand for a water treatment method using an advanced oxidation process technology capable of treating wastewater with high efficiency and treating a large amount in a short time without generating odor.

In the past, various attempts have been made to improve the water treatment efficiency of an advanced oxidation treatment process. To improve the contact area of ozone, a plurality of reactors are installed or fine ozone bubbles are formed to increase the decomposition reaction efficiency by increasing the contact efficiency of ozone. A method using dissolved ozone flotation (DOF) has been attempted.

In addition, in order to increase the decomposition efficiency of ozone, by irradiating ultraviolet (UV) and installing a perforated plate around the ultraviolet lamp, the ozone passes around the lamp and induces the decomposition reaction of ozone in the vicinity of the lamp. The photocatalyst is coated on a porous plate, and the photocatalyst irradiated with ultraviolet rays decomposes ozone to improve the decomposition reaction efficiency by OH radicals.

The advanced oxidation process using the conventional dissolved ozone flotation (DOF) method is to pressurize the gaseous ozone to a high pressure by using a compressor to improve the solubility of the ozone, and the waste water pressurized by the pressure pump. Pressurized ozone is added to dissolve it. Thereafter, by discharging this to atmospheric waste water, ultra-fine ozone bubbles are generated to float floating materials while the ozone floats upward, or react with contaminants to remove contaminants.

This can increase the contact efficiency by reducing the size of the ozone bubble to increase the specific surface area can increase the decomposition reaction efficiency of most organic pollutants, which is faster and more efficient than the biological decomposition method.

However, the amount of ozone introduced is limited to the amount that can be dissolved in water under normal pressure, and escapes into the air as soon as it floats on the surface of the water, so the degree of participation of gaseous ozone in the decomposition reaction is relatively small to increase the reaction efficiency. There is a limit.

In addition, since most of the added ozone exists in the form of bubbles, decomposition reaction of ozone and pollutants occurs through the gas-liquid interface, and thus, the decomposition reaction rate is slow when a large amount of pollutants are actually processed. Because of this, there may be a substance that can not react with ozone at all, and when the inflow of hardly decomposable substances such as pesticides, synthetic detergents in sewage or waste water increases, there is a limit to ozone treatment alone.

To solve this problem, ozone + hydrogen peroxide (H ₂ O ₂ ), ozone + ultraviolet, There is an advanced oxidation process using ozone + photocatalyst + ultraviolet, ozone + ultrasound.

However, since most of the ozone injected is in the form of bubbles, as the amount of ozone is increased, a large amount of bubbles are generated to obstruct the irradiation of ultraviolet rays, and as the level rises above the water surface, the background pressure decreases, thereby increasing the size of the bubbles, rather than contaminants. Decreased contact efficiency with This has a problem that the oxidation reaction by ozone and the amount of OH radicals are reduced rather than the decomposition reaction efficiency.

In addition, since unreacted ozone is not properly utilized and released into the atmosphere or decomposed by a decomposing device, the use efficiency of ozone is very low. There is an increasing problem.

In addition, conventionally, since an ultraviolet lamp for generating ultraviolet rays is immersed in sewage, the ultraviolet lamp or a protective device (quartz tube, etc.) is forced to directly contact the sewage. As a result, as the use time elapses, moss or moss is generated on the surface of the ultraviolet lamp or the protective device by the contaminated water, and foreign matters are attached to the ultraviolet ray, thereby preventing the transmission of ultraviolet rays. In addition, since the ultraviolet lamp is in direct contact with the sewage, the lamp life is shortened, and there is a problem that an ultraviolet lamp cleaning device is required.

The present invention devised to solve the problems of the prior art as described above by using the oxidizing strong OH radicals generated by the reaction of ozone and ultraviolet rays, to increase the decomposition performance and sterilization efficiency of contaminants contained in the water to be treated. It is an object of the present invention to provide a water treatment apparatus and a method using a non-contact lamp and a pressurized ozone to be made.

In addition, the present invention provides a non-contact lamp and pressure that can prevent the contamination of the ultraviolet lamp by contaminants by placing a gas layer between the ultraviolet lamp and the contaminated water to prevent direct contact between the ultraviolet lamp and the protective device. Another object is to provide a water treatment apparatus and method using ozone.

In addition, the present invention is to provide a water treatment apparatus and method using a non-contact lamp and pressurized ozone capable of increasing the decomposition rate and sterilization efficiency of the contaminants by applying pressure to increase the dissolved rate of ozone by applying a pressure tank. There is a purpose.

The object of the present invention is a water treatment device, pressure tank; A lamp unit immersed in the pressure tank and emitting ultraviolet rays; And a ozone treatment unit for treating the ozone contained in the water to be treated through the pressure tank, wherein the ozone is dissolved in the water to be treated in the pressure tank. Is achieved by

In addition, the lamp unit of the present invention the lower surface is open; An ultraviolet lamp installed inside the housing to generate ultraviolet rays; And a gas layer which protects the ultraviolet lamp from contact with the water to be treated.

In addition, the lamp unit of the present invention detects the water level in the housing to adjust the gas supply amount to maintain a constant gas level by maintaining a constant gas level; And preferably connected to the housing further comprises a gas supply pipe for supplying gas.

In addition, the lamp unit of the present invention preferably further comprises a reflector to reflect the ultraviolet light generated from the ultraviolet lamp to maximize the ultraviolet irradiation intensity.

Another object of the present invention is to provide a water treatment apparatus module, comprising: a housing for applying pressure; An ultraviolet lamp installed inside the housing and generating ultraviolet light; And a gas layer which protects the ultraviolet lamp from contact with the water surface, wherein ozone is dissolved in the water to be treated in the housing, and a water treatment device using a non-contact lamp and a pressurized ozone in which the water to be treated flows into the housing. Is achieved by.

In addition, the water treatment device module of the present invention detects the water level in the housing to adjust the amount of gas supply to maintain a constant gas level by maintaining a constant water level; And preferably connected to the housing further comprises a gas supply pipe for supplying gas.

In addition, the housing of the present invention further includes a reflector for maximizing ultraviolet irradiation intensity by reflecting ultraviolet rays generated from an ultraviolet lamp and a gas barrier membrane for transmitting ultraviolet rays to block ozone gas while preventing the corrosion of the reflector. It is preferable that it is configured.

In addition, the ultraviolet lamp of the present invention is preferably configured by selecting any one or more of the ultraviolet lamp for sterilization, ultraviolet lamp for ozone generation and multi-wavelength lamp.

In addition, it is preferably configured to further comprise a filtration membrane for filtering the water to be treated of the present invention.

In addition, the ozone of the present invention is preferably supplied from the ozone generator connected to the pressure tank or the housing.

In addition, the ozone of the present invention is preferably generated by irradiating the ultraviolet light generated from the ultraviolet lamp to the air or oxygen supplied from the gas supply pipe.

In addition, another object of the present invention is a first step of pumping the water to be stored stored in the reservoir to the pressure tank; Dissolving ozone supplied to the pressure tank in the water to be treated; A third step of causing contaminants to be decomposed and sterilized by an oxidation reaction with OH radicals generated by reacting ozone or ultraviolet rays treated or dissolved by ultraviolet rays irradiated with the ozone or ultraviolet lamps; And a fourth step of treating the ozone through the ozone treatment unit by treating the treated water with oxidation.

In addition, the first step of the present invention preferably comprises a step of performing filtration through a filtration membrane before pumping the water to be treated to the pressure tank.

In addition, the ozone of the present invention is preferably generated by irradiating ultraviolet light to the air or oxygen supplied from the ozone generator or gas supply pipe.

In addition, prior to the first step of the present invention, it is preferable to perform a biological treatment process.

In addition, after the third step of the present invention, it is preferable to perform any one of activated carbon filtration, membrane separation filtration.

In addition, the third step of the present invention is preferably the pressure tank includes a water treatment by adding any one catalyst selected from manganese or titanium.

Therefore, the water treatment apparatus and method using the non-contact lamp and the pressurized ozone of the present invention is a water treatment using the oxidizing strong OH radicals generated by the reaction of ozone and ultraviolet light, the decomposition performance and sterilization of contaminants contained in the water to be treated. There is a remarkable and advantageous effect of increasing the efficiency.

In addition, the water treatment apparatus and method using the non-contact lamp and the pressurized ozone of the present invention by placing a gas layer between the UV lamp and the contaminated water to prevent the UV lamp and the protection device from directly contacting the water, There is a noticeable and advantageous effect of preventing contamination of the ultraviolet lamp.

In addition, the water treatment apparatus and method using the non-contact lamp and the pressurized ozone of the present invention is not significantly affected by the water temperature, can increase the ultraviolet emission efficiency, and has a remarkable and advantageous effect of reducing the temperature deviation.

In addition, the water treatment apparatus and method using a non-contact lamp and a pressurized ozone of the present invention forms a gas barrier film between the lamp and the gas layer to transmit ultraviolet rays, but to block ozone gas, thereby preventing corrosion of the reflector.

In addition, the water treatment apparatus and method using the non-contact lamp and the pressurized ozone of the present invention does not require the ultraviolet lamp cleaning equipment, etc., the configuration of the device is simple, and the maintenance is convenient and advantageous effects.

The terms or words used in this specification and claims are not to be construed as being limited to their ordinary or dictionary meanings, and the inventors may appropriately define the concept of terms in order to best describe their invention. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing a water treatment apparatus using a non-contact lamp and a pressurized ozone according to a first embodiment of the present invention. The water treatment apparatus of the present invention is a storage tank 100, pump 120, filtration membrane 130, ozone generator 140, pressure tank 150, ozone 160, ozone treatment unit 170, lamp unit 200 It is configured to include).

The storage tank 100 temporarily stores the water to be treated 110 containing contaminants, and the filtration membrane 130 removes particulate matter or the like prior to sending the water to be treated 110 to the pressure tank 150. It acts as a filter.

The ozone generating unit 140 serves to supply ozone in the pressure tank 150, and because it is not an essential device, it may be selectively installed as necessary, or may not be installed.

The pressure tank 150 is a device that maintains a pressurized state by applying a pressure in order to dissolve the ozone 160 in water well, and a substantial oxidation process by ozone, ultraviolet rays and OH radicals occurs, and the ozone generating unit 140 is an apparatus for injecting ozone 160 into the pressure tank.

In addition, the lamp unit 200 is an apparatus for generating ultraviolet rays 280 for treating the water to be treated 110. The ozone treatment unit 170 is a device for treating the ozone dissolved in the treated water after the ozone treatment is finished. One or more lamp units 200 may be installed in the pressure tank, and a plurality of lamp units may be modularized and combined to increase processing efficiency as necessary.

2 is a view showing a lamp configuration of the present invention.

The lamp unit 200 includes a housing 210, an ultraviolet lamp 220, a gas layer 230, a reflector 240, a water level detector 250, a gas supply pipe 260, and a gas supply source 270.

The housing 210 has an open lower surface, and the ultraviolet lamp 220 is fixed to the housing 210. The housing 210 having the ultraviolet lamp 220 is immersed in the pressure tank 150 (see FIG. 1).

The ultraviolet lamp 220 generates ultraviolet light 280 to treat the water to be treated and reacts with ozone dissolved in the pressure tank 150 to generate OH radicals having strong oxidizing power.

In addition, the reflector plate 240 is installed inside the housing, and reflects the ultraviolet rays 280 generated by the ultraviolet lamp 220 and irradiated to the upper part to maximize the amount of ultraviolet rays transmitted to the water to be treated. The water level detector 250 detects the level of the water to be treated in the housing to adjust the gas supply.

The lamp unit 200 of the present invention supplies a gas (air, oxygen, etc.) into the housing 210 to form the gas layer 230 such that the ultraviolet lamp 220 does not directly contact the surface of the target water. It is characterized by. In addition, ozone is generated by irradiating air, oxygen, etc., present in the gas layer with ultraviolet rays, and OH radicals are generated by the reaction of the generated ozone with ultraviolet rays.

In addition, the water treatment device of the present invention is installed by the water level detector 250, even when the pressure changes in the gas layer by maintaining the constant gas layer 230 is not reduced in the inside of the housing 210, the ultraviolet lamp 220 is treated Make sure you are always in contact with water.

When the gas layer 230 decreases due to the pressure increase inside the pressure tank 150 and the water level in the housing 210 reaches the upper limit of the set water level, the water level detector 250 detects this and the gas supply pipe 260. To supply gas through When the water level in the housing 210 reaches the lower limit of the set water level due to the gas supply, the water level detector 250 detects this to stop the gas supply.

By repeating the gas supply step and the gas supply stop step, the water level is kept constant between the upper and lower water level limits, and the gas layer 230 is kept constant so that the ultraviolet lamp 220 does not come into contact with the water to be treated. To protect.

For this reason, the protection device, such as a quartz tube, is not needed, and the contamination of the ultraviolet-ray lamp 220 by the contaminants, such as moss, also does not generate | occur | produce. Therefore, the UV transmittance is increased, the water treatment efficiency is increased, there is no need to clean the lamp, there is an advantage that the device is also simple.

However, if necessary, the ultraviolet lamp 220 may be provided with a protective device selected from a quartz tube, a glass tube, and a fluorine resin tube. These protective devices are preferably made of a material having a high UV transmittance so that ultraviolet light can pass through well.

Since the ultraviolet lamp 220 of the present invention is non-contact with the water to be treated, it is not significantly affected by the water temperature, thereby increasing efficiency, and reducing the temperature deviation than the conventional contact method. In general, in the case of a low-pressure low-output lamp, when the surface temperature of the lamp is 40 ℃, the ultraviolet irradiation intensity is the highest and the efficiency is high.

The ultraviolet lamp 220 of the present invention is composed of a lamp of the sterilization wavelength band (253.7nm) for the purpose of sterilization only, it is preferable to install a lamp of the ozone generation wavelength band (184.9nm) when additional ozone generation is required. If necessary, a suitable combination of these two (253.7 nm and 184.9 nm wavelength combinations) can also be configured, and a multi-wavelength lamp or the like can be provided according to the purpose.

3A to 3C are views showing various forms of the reflecting plate of the present invention. The present invention can form the reflector 240 in various forms. In addition, in order to prevent corrosion of the reflector due to the ozone, ultraviolet rays may be transmitted, but a gas barrier layer 290 made of a material such as quartz or fluorine resin, which may block gas such as ozone gas, may be additionally installed.

First, as shown in FIG. 3A, the end of the reflector 240 is in contact with the inner wall of the housing 210. In this case, no gas is filled in the space between the housing 210 and the reflector 240, and a gas layer is formed only inside the reflector 240. Therefore, since the vaporized high temperature water vapor is cooled by direct contact with the outside of the low temperature, water vapor condenses inside the reflector 240.

Second, as shown in FIG. 3B, the end of the reflector 240 and the inner wall of the housing 210 are spaced apart, and a space exists therebetween. In this case, a gas layer may also be formed in the space between the reflecting plate 240 and the housing 210 to convection the vaporized high temperature steam. Therefore, by reducing the temperature difference between the inside and the outside of the reflecting plate 240 to prevent water vapor condensation inside the reflecting plate 240, the ultraviolet reflectance can be kept constant.

Third, as shown in FIG. 3C, the reflecting plate 240 is partially installed on the inner wall of the housing 210. This may selectively install the reflecting plate 240 only in the part where the ultraviolet rays are highly reflected.

4 to 5 is a view showing that the ultraviolet lamp is installed in the reflector according to the present invention. The ultraviolet lamp can be composed of only the sterilizing ultraviolet lamp 310 as shown in Figure 4, in order to induce an increase in the water treatment efficiency according to the interaction of ozone and ultraviolet rays as shown in Figure 5 sterilizing ultraviolet lamp 410 and ozone generation The ultraviolet ray lamp 420 may be installed in combination. The space between the ultraviolet lamps represents the gas layers 320, 430.

6A to 6B are cross-sectional views illustrating a water treatment device module using a non-contact lamp and a pressurized ozone according to a second embodiment of the present invention, and FIGS. 7A to 7B illustrate a non-contact lamp and a pressurized ozone according to a third embodiment of the present invention. It is sectional drawing which shows the water treatment apparatus module using this. 8 shows that a plurality of ultraviolet lamps are mounted in a water treatment device module using a non-contact lamp and a pressurized ozone of the present invention.

6A to 6B show that one lamp is installed in the module (FIG. 6A shows a configuration including a gas barrier film, and FIG. 6B shows a configuration without a gas barrier film). It shows that a plurality of lamps are provided.

The water treatment device module 500 of the present invention includes a housing 510, an ultraviolet lamp 520, a power connector 550, and a gas layer 560. Although not shown in the drawing, a gas supply pipe and a gas supply source are connected to the housing 510 to supply the gas to form the gas layer 560 to protect the ultraviolet lamp from contact with the surface of the water. In addition, the water level sensor 530, the reflector 540 or the gas barrier layer 590 may be further included.

The ozone generator 570 for supplying ozone to the water treatment device module 500 may be selectively installed as necessary, or may not be installed.

When the ozone generator 570 is not present, ozone generated by reacting the ultraviolet light emitted from the ultraviolet lamp 520 with the air or oxygen supplied into the housing 510 by the gas supply pipe and the gas supply source is dissolved in the water to be treated. Is supplied.

The two methods can be selected and used according to need, and the ozone generator 140 is not an essential device, and thus may be selectively installed as necessary or may not be installed. In addition, the amount of ozone introduced may be adjusted according to the indication value of the water level meter installed in the upper portion of the pressure tank.

The water treatment device module 500 is not immersed in the water to be treated, but is formed in a non-immersion type. The water treatment device module 500 is allowed to flow into the module and then to be discharged.

Therefore, if the water treatment apparatus is modularized, it can be easily manufactured, and one or more modules can be conveniently configured and installed as shown in FIG. 7 to easily cope with fluctuations in water treatment capacity. In addition, because it is not immersed, unlike the conventional immersion type ultraviolet device, there is no need for a separate device for stabilization of the water to be treated, it is possible to significantly reduce the cost of civil engineering.

9 and 10 are flowcharts illustrating a water treatment method according to each embodiment of the present invention.

Referring to Figure 9, the water treatment method according to the present invention proceeds through the process of introducing the water to be treated and stored in the storage tank, the water to be oxidized through a pressure tank (oxidation reaction tank), passing through the ozone treatment unit. .

Referring to FIG. 10, the water treatment method according to the present invention further includes a step of introducing the water to be treated and storing it in a storage tank and then filtering the filter with a filtration membrane. Thereafter, the water to be treated is oxidized through a pressure tank (oxidation reaction tank), and the process proceeds through a process of an ozone treatment unit.

The water treatment method using the advanced oxidation treatment process according to the present invention will be described with reference to FIGS. 1 and 2.

First, the treated water containing the biological treatment or the biologically treated contaminants is stored in the storage tank 100. Then, the water to be treated 110 is pumped by the pump 120 and moved to the filtration membrane 130 to be filtered, and then transferred to the pressure tank 150.

Here, the process of filtering by the filtration membrane 130 may be omitted as necessary, and is not essential. Types of filtration membranes that can be used include microfiltration membranes (MF), ultrafiltration membranes (UF), nanofiltration membranes (NF), and reverse osmosis membranes (RO).

The water to be treated 110 transferred to the pressure tank 150 may directly react with the ozone 160 supplied into the pressure tank by the ozone generating means, or may be directly treated by ultraviolet rays generated from the ultraviolet lamp 220. In addition, it may be treated by a strong oxidation reaction with the OH radicals generated by the reaction of the ultraviolet light 280 irradiated from the ultraviolet lamp 220 and the ozone 160.

The method for supplying ozone to the pressure tank 150 is as follows.

First, a method of supplying ozone generated by installing the ozone generator 140 separately to the outside of the pressure tank 150 into the pressure tank 150.

Second, ozone generated by reacting the ultraviolet light emitted from the ultraviolet lamp 220 with the air or oxygen supplied into the housing 210 by the gas supply source 270 and the gas supply pipe 260 reacts with the treated water. That's how it is.

The two methods can be selected and used according to need, and the ozone generator 140 is not an essential device, and thus may be selectively installed as necessary or may not be installed. In addition, the amount of ozone introduced may be adjusted according to the indication value of the water level meter installed in the upper portion of the pressure tank.

Through the above process, the contaminants contained in the water to be treated 110 are decomposed and E. coli is sterilized at the same time. Finally, the oxidized and sterilized water 110 is discharged after the ozone is treated in the ozone treatment unit 170.

At this time, if it is not possible to meet the water quality standards only by the above process, it is possible to add a catalyst material such as manganese or titanium system in the pressure tank or add an activated carbon filtration process to the rear end. In addition, when biological treatment is required as a pretreatment process, a biological treatment process may be added to the front of the reservoir.

In addition, when the degree of contamination is not severe depending on the material to be treated, unnecessary steps may be omitted.

The water treatment apparatus and method using the non-contact lamp and pressurized ozone of the present invention exhibit excellent sterilizing and oxidizing power without leaving toxicity. In other words, the oxidizing power is much stronger than the existing oxidizing agents such as chlorine, chlorine dioxide, and potassium permanganate, and the reaction rate can be increased by at least 10 to 10,000 times without leaving toxic or residues compared to using ozone alone.

In addition, OH radicals produced by the reaction of UV and ozone have strong oxidizing ability, and are sterilized, disinfected, surface activated, hardly decomposable organic substances, oxidative decomposition, discoloration, deodorization, deodorization, carcinogenic substances (THM) It can be applied to various fields such as generation suppression.

The OH radical can be treated with ultrapure water due to an even sterilization effect regardless of strains, and as well as aseptic treatment to increase the freshness of the water quality to prevent the scale of the water tank and the inside of the pipe, purifying ground water, sterilization of high purity It can have an excellent effect on purification, food sterilization, agricultural product sterilization, seafood sterilization.

Apparatus and method for water treatment using a non-contact lamp and pressurized ozone according to the present invention can be used in all fields that require water treatment throughout the industry, such as sewage treatment plants, wastewater treatment plants, manure treatment plants, and production processes of factories.

Applicable fields include pharmaceutical companies, soft drink factories, agricultural and marine products factories, horticultural cultivation, pesticide-free cultivation, agricultural and marine product vaults, textile factories, dyeing factories, electronics industries, hotels, food manufacturing and processing companies, general hospitals, apartment complexes, broadcasting stations, etc. It can be used for the purpose and is more efficient than the existing method of treating with chemicals, and it can generate economic benefits by reducing the use of water in addition to the cost of purchasing chemicals and labor.

The present invention has been shown and described with reference to the preferred embodiments as described above, but is not limited to the above embodiments and those skilled in the art without departing from the spirit of the present invention. Various changes and modifications will be possible.

1 is a cross-sectional view showing a water treatment apparatus using a non-contact lamp and a pressurized ozone according to a first embodiment of the present invention.

2 is a view showing the ultraviolet lamp configuration of the present invention

3A to 3C are views showing various forms of the reflecting plate of the present invention.

Figure 4 is a view showing that the ultraviolet lamp for sterilization of the present invention is installed

5 is a view showing a combination of UV lamp for sterilization and ozone generation of the present invention in combination

6A to 6B are cross-sectional views of a water treatment device module using a non-contact lamp and a pressurized ozone according to a second embodiment of the present invention.

7A to 7B are cross-sectional views illustrating a water treatment device module using a non-contact lamp and a pressurized ozone according to a third embodiment of the present invention.

8 is a view showing a plurality of ultraviolet lamps mounted on the non-contact water treatment apparatus module of the present invention.

9 to 10 are flowcharts illustrating a water treatment method according to each embodiment of the present invention.

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

100: reservoir 110: water to be treated

120: pump 130: filtration membrane

140: ozone generating unit 150: pressure tank

160: ozone 170: ozone treatment unit

200: lamp unit 210: housing

220: ultraviolet lamp 230: gas layer

240: reflector 250: water level detector

260: gas supply pipe 270: gas supply source

280: UV 290: gas barrier membrane

Claims (20)

In the water treatment apparatus, Pressure tank; A lamp unit immersed in the pressure tank and emitting ultraviolet rays; And An ozone treatment unit for treating the ozone contained in the water to be treated through the pressure tank, A water treatment apparatus using a non-contact lamp and pressurized ozone in which ozone is dissolved in the water to be treated in the pressure tank. The method of claim 1, The lamp unit A housing having an open lower surface; An ultraviolet lamp installed inside the housing to generate ultraviolet rays; And Gas layer to protect the ultraviolet lamp from contact with the water to be treated Water treatment apparatus using a non-contact lamp and pressure ozone comprising a. The method of claim 2, The lamp unit A water level sensor that maintains a constant level by sensing a level in the housing to adjust a gas supply to maintain a constant gas layer; And A gas supply pipe connected to the housing to supply gas Water treatment device using a non-contact lamp and pressurized ozone further comprising. The method according to claim 2 or 3, The lamp unit is a water treatment device using a non-contact lamp and pressure ozone further comprises a reflector for maximizing the ultraviolet irradiation intensity by reflecting the ultraviolet light generated from the ultraviolet lamp. The method of claim 2, Non-contact lamp and pressurized ozone further comprising a gas barrier film between the ultraviolet lamp and the gas layer. In the water treatment apparatus module, A housing for applying pressure; An ultraviolet lamp installed inside the housing and generating ultraviolet light; And Gas layer to protect the ultraviolet lamp from contact with water Including, Ozone is dissolved in the water to be treated in the housing, and a water treatment device using a non-contact lamp and a pressurized ozone in which the water to be treated flows into the housing. The method of claim 6, The water treatment device module, A water level sensor that maintains a constant level by sensing a level in the housing to adjust a gas supply to maintain a constant gas layer; And A gas supply pipe connected to the housing to supply gas Water treatment device using a non-contact lamp and pressurized ozone further comprising. The method of claim 6, The housing is a water treatment device using a non-contact lamp and pressure ozone further comprises a reflector to reflect the ultraviolet light generated from the ultraviolet lamp to maximize the ultraviolet irradiation intensity. The method of claim 6, Non-contact lamp and pressurized ozone further comprising a gas barrier film between the ultraviolet lamp and the gas layer. The method according to claim 5 or 9, The gas barrier membrane is a water treatment apparatus using a non-contact lamp and a pressurized ozone composed of one of quartz or fluorine resin. The method according to claim 2 or 6, The ultraviolet lamp is a water treatment device using a non-contact lamp and a pressurized ozone configured by selecting any one or more of a UV lamp for sterilization, an UV lamp for ozone generation, and a multi-wavelength lamp. The method according to claim 1 or 6, A water treatment apparatus using a non-contact lamp and pressure ozone further comprising a filtration membrane for filtering the water to be treated. The method according to claim 1 or 6, The ozone is a water treatment apparatus using a non-contact lamp and a pressurized ozone supplied from the ozone generator connected to the pressure tank or the housing. The method according to claim 1 or 6, The ozone is a water treatment device using a non-contact lamp and a pressurized ozone generated by irradiating the ultraviolet light generated from the ultraviolet lamp to the air or oxygen supplied from the gas supply pipe. A first step of pumping the water to be stored in the reservoir to a pressure tank; Dissolving ozone supplied to the pressure tank in the water to be treated; A third step of causing contaminants to be decomposed and sterilized by an oxidation reaction with OH radicals generated by reacting ozone or ultraviolet rays treated or dissolved by ultraviolet rays irradiated with the ozone or ultraviolet lamps; And A fourth step of treating the ozone by passing the oxidized water to be treated through an ozone treatment unit; Water treatment method using a non-contact lamp and pressurized ozone comprising a. The method of claim 15, The first step, Non-contact lamp and pressurized ozone water treatment method comprising the step of performing the filtration through the filtration membrane before pumping the water to be treated to the pressure tank. The method of claim 15, The ozone is a water treatment method using a non-contact lamp and a pressurized ozone generated by irradiating ultraviolet light to the air or oxygen supplied from the ozone generator or gas supply pipe. The method of claim 15, Before the first step, the water treatment method using a non-contact lamp and pressure ozone further comprising a biological treatment process. The method of claim 15, After the third step, the water treatment method using a non-contact lamp and pressurized ozone which further performs any one of activated carbon filtration, membrane separation filtration. The method of claim 15, The third step is The pressure tank is a water treatment method using a non-contact lamp and pressurized ozone comprising a water treatment by inputting any one catalyst selected from manganese or titanium.

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