KR102422723B1 - Water treatment apparatus capable of changing operation mode in response to water quality characteristics and water treatment method based on it - Google Patents

Abstract

Disclosed are a water treatment apparatus capable of changing an operation mode in response to water quality characteristics and a water treatment method based thereon.
The water purification method includes: a pretreatment unit for lowering the turbidity of the water to be treated by a flock precipitation method, while being connected to the inlet of the water to be treated and the first connecting pipe; a water purification unit for removing particulate matter contained in the water to be treated while being connected to the pretreatment unit by a second connection pipe; a reverse osmosis unit that applies a pressure higher than the osmotic pressure while being connected to the water purification unit and the third connecting pipe to allow only pure water, of the water to be treated, to pass through the separation membrane; and a sterilization unit that sterilizes harmful bacteria and harmful bacteria by irradiating ultraviolet rays to the water to be treated, while being connected to the reverse osmosis unit and the fourth connection pipe, and preventing re-reproduction of microorganisms by introducing chlorine. It further includes a bypass unit for bypassing a specific unit among the units according to the turbidity and salinity of the water, wherein the bypass unit includes: a first bypass pipe for bypassing the treatment water introduction unit and the purified water unit; a second bypass pipe that bypasses the water purification unit and the sterilization unit; a first opening/closing valve that selectively opens and closes the first connection pipe or the first bypass pipe while being installed at a branch point between the target water introduction part and the first bypass pipe; a second opening/closing valve for selectively opening and closing the third connecting pipe while being installed in the third connecting pipe; and a third opening/closing valve which is installed in the second bypass pipe and selectively opens and closes the second bypass pipe, wherein the pre-treatment unit is composed of a coagulant and a settling tank, and the water purification unit is a backwash filter and a plurality of filtration filters, wherein the reverse osmosis unit includes a micro filter and a reverse osmosis member, and the sterilization unit further includes an ultraviolet sterilization lamp and a chlorine injection member, the pretreatment unit, the water purification unit, and the reverse osmosis unit. Each component of the unit and the sterilization unit is configured in a modular type, and further includes being installed horizontally by a flange joint, installed in a section between the water purification unit and the sterilization unit, and injecting a washing solution into the vessel of the reverse osmosis unit and a reverse osmosis membrane washing member for washing the reverse osmosis membrane installed in the vessel with a washing solution by immersing it for a predetermined time and then discharging, wherein the reverse osmosis membrane washing member includes: a washing solution storage tank; a washing solution supply pipe connecting the outlet of the washing solution storage tank and the outlet of the third connecting pipe; a contaminated water discharge pipe connecting the outlet of the vessel and the washing solution storage tank; and a pressure pump that supplies the washing solution to the inside of the vessel through the washing solution supply pipe, and pumps the contaminated water to the washing solution storage tank through the contaminated water discharge pipe after the reverse osmosis membrane inside the vessel is immersed for a certain period of time. In a water purification method using a water purification apparatus that can change the operation mode according to the water quality characteristics to be used, the first connection By blocking the pipe and opening the first bypass pipe, the introduced water to be treated bypasses the pre-treatment unit and transfers to the water purification unit, and blocks the third connection pipe and opens the second bypass pipe. The first water purification mode is executed so that the water to be treated, which has passed through the water purification unit, bypasses the reverse osmosis unit and is transferred to the sterilization unit, and the water quality of the water to be treated introduced through the treatment water introduction unit is high in turbidity and low salinity. Under the condition, the first connecting pipe is opened and the first bypass pipe is blocked so that the introduced target water is transferred to the pretreatment unit and the water purification unit, and the third connecting pipe is blocked and the second bypass pipe is blocked. The second water purification mode is executed so that the water to be treated, which has passed through the water purification unit, bypasses the reverse osmosis unit and is transferred to the sterilization unit by opening the pass pipe, and the quality of the water to be treated introduced through the water treatment unit is changed. In high turbidity and high salinity conditions, the first connection pipe is opened and the first bypass pipe is blocked so that the introduced water to be treated passes through the pretreatment unit and the water purification unit sequentially, and the third connection pipe is connected A third water purification mode is executed in which the water to be treated that has passed through the water purification unit passes through the reverse osmosis unit and the sterilization unit sequentially by opening the second bypass pipe and is introduced through the treatment water introduction unit. When the quality of the water to be treated is in low turbidity and high salinity conditions, the first connection pipe is blocked and the first bypass pipe is opened so that the water to be treated bypasses the pretreatment unit and is transferred to the water purification unit. and opening the third connecting pipe and also opening the second bypass pipe. It is characterized in that the fourth water purification mode is executed so that the target water passing through the water purification unit passes through the reverse osmosis unit and the sterilization unit sequentially by blocking.

Description

Water treatment apparatus capable of changing operation mode in response to water quality characteristics and water treatment method based on it

The present invention relates to the field of water treatment.

More specifically, it is possible to increase the water treatment efficiency by selecting and operating an operation mode suitable for the properties (turbidity and salinity) of the raw water, and to facilitate the expansion and reduction of each unit component constituting the water treatment system. It relates to a water purification apparatus capable of changing an operation mode corresponding to a water quality shape having a modular structure and a water purification method based thereon.

Unless otherwise indicated herein, the content described in this section is not prior art to the claims of this application, and inclusion in this section does not presuppose that it is prior art.

In general, groundwater, valley water, river water, and river water used as raw water contain a lot of metal ions such as iron and manganese and organic matter as well as general bacteria, Escherichia coli, and Escherichia coli. In the case of , it is impossible to use drinking water due to its high salinity, so it is purified by a water treatment device and used as drinking and living water.

However, since the conventional water treatment apparatus is operated uniformly regardless of the quality of raw water, it undergoes an unnecessary water purification step, so there is a problem in that the water purification efficiency is lowered.

1. Registered Patent Publication No. 1190031 2. Registered Patent Publication No. 1504545

One object of the present invention is to select and operate an operation mode suitable for the properties (turbidity and salinity) of raw water, thereby reducing maintenance costs and changing the operation mode in response to water quality properties that can shorten treatment time. A water treatment device is provided.

Another object of the present invention is to provide a water purification apparatus capable of changing an operation mode in response to water quality characteristics having a modular structure in which unit components are detachable so that each unit component can be expanded and installed as needed.

Another object of the present invention is to provide a water purification method using the above-described water treatment apparatus.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. There will be.

The present invention for achieving the above object is a pretreatment unit for lowering the turbidity of the water to be treated by a flock precipitation method, while being connected to the inlet of the water to be treated and the first connection pipe; a water purification unit for removing particulate matter contained in the water to be treated while being connected to the pretreatment unit by a second connection pipe; a reverse osmosis unit that applies a pressure higher than the osmotic pressure while being connected to the water purification unit and the third connecting pipe to allow only pure water, out of the water to be treated, to pass through the separation membrane; and a sterilization unit that sterilizes harmful bacteria and harmful bacteria by irradiating ultraviolet rays to the water to be treated, while being connected to the reverse osmosis unit and the fourth connection pipe, and preventing re-reproduction of microorganisms by introducing chlorine. It further includes a bypass unit for bypassing a specific unit among the units according to the turbidity and salinity of the water, wherein the bypass unit includes: a first bypass pipe for bypassing the treatment water introduction unit and the purified water unit; a second bypass pipe that bypasses the water purification unit and the sterilization unit; a first opening/closing valve that selectively opens and closes the first connection pipe or the first bypass pipe while being installed at a branch point between the target water introduction part and the first bypass pipe; a second opening/closing valve for selectively opening and closing the third connecting pipe while being installed in the third connecting pipe; and a third opening/closing valve which is installed in the second bypass pipe and selectively opens and closes the second bypass pipe, wherein the pre-treatment unit is composed of a coagulant and a settling tank, and the water purification unit is a backwash filter and a plurality of filtration filters, wherein the reverse osmosis unit includes a micro filter and a reverse osmosis member, and the sterilization unit further includes an ultraviolet sterilization lamp and a chlorine injection member, the pretreatment unit, the water purification unit, and the reverse osmosis unit. Each component of the unit and the sterilization unit is configured in a modular type, and further includes being installed horizontally by a flange joint, installed in a section between the water purification unit and the sterilization unit, and injecting a washing solution into the vessel of the reverse osmosis unit and a reverse osmosis membrane washing member for washing the reverse osmosis membrane installed in the vessel with a washing solution by immersing it for a predetermined time and then discharging, wherein the reverse osmosis membrane washing member includes: a washing solution storage tank; a washing solution supply pipe connecting the outlet of the washing solution storage tank and the outlet of the third connecting pipe; a contaminated water discharge pipe connecting the outlet of the vessel and the washing solution storage tank; and a pressure pump that supplies the washing solution to the inside of the vessel through the washing solution supply pipe, and pumps the contaminated water to the washing solution storage tank through the contaminated water discharge pipe after the reverse osmosis membrane inside the vessel is immersed for a certain period of time. In a water purification method using a water purification apparatus that can change the operation mode according to the water quality characteristics to be used, the first connection By blocking the pipe and opening the first bypass pipe, the introduced water to be treated bypasses the pre-treatment unit and transfers to the water purification unit, and blocks the third connection pipe and opens the second bypass pipe. The first water purification mode is executed so that the water to be treated, which has passed through the water purification unit, bypasses the reverse osmosis unit and is transferred to the sterilization unit, and the water quality of the water to be treated introduced through the treatment water introduction unit is high in turbidity and low salinity. Under the condition, the first connecting pipe is opened and the first bypass pipe is blocked so that the introduced target water is transferred to the pretreatment unit and the water purification unit, and the third connecting pipe is blocked and the second bypass pipe is blocked. The second water purification mode is executed so that the water to be treated, which has passed through the water purification unit, bypasses the reverse osmosis unit and is transferred to the sterilization unit by opening the pass pipe, and the quality of the water to be treated introduced through the water treatment unit is changed. In high turbidity and high salinity conditions, the first connection pipe is opened and the first bypass pipe is blocked so that the introduced water to be treated passes through the pretreatment unit and the water purification unit sequentially, and the third connection pipe is connected A third water purification mode is executed in which the water to be treated that has passed through the water purification unit passes through the reverse osmosis unit and the sterilization unit sequentially by opening the second bypass pipe and is introduced through the treatment water introduction unit. When the quality of the water to be treated is in low turbidity and high salinity conditions, the first connection pipe is blocked and the first bypass pipe is opened so that the water to be treated bypasses the pretreatment unit and is transferred to the water purification unit. and opening the third connecting pipe and also opening the second bypass pipe. There is provided a purified water treatment method, characterized in that the fourth water purification mode is executed so that the target water passing through the water purification unit passes through the reverse osmosis unit and the sterilization unit sequentially by blocking.

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Preferably, for washing the reverse osmosis membrane installed inside the vessel of the reverse osmosis unit, in a state in which the introduction of the target water is stopped, the pressure pump is operated to remove the washing solution in the washing solution storage tank through the washing solution supply pipe of the reverse osmosis unit. supply to the inside of the vessel, stop the operation of the pressure pump, and maintain the state in which the reverse osmosis membrane is immersed in the washing solution supplied to the inside of the vessel for a set time to remove foreign substances attached to the reverse osmosis membrane, When the set time has elapsed, the pressure pump may be restarted to recover the contaminated water contaminated by the washing inside the vessel to the washing solution storage tank through the contaminated water discharge pipe.

According to an embodiment of the present invention, by selecting and operating an operation mode suitable for the properties (turbidity and salinity) of raw water, the efficiency of water treatment can be increased, and each unit component constituting the water treatment device can be expanded and It has the advantage of being easy to install.

It should be understood that the present invention is not limited to the above-described effects, and includes all effects that can be inferred from the configuration of the invention described in the detailed description or claims.

1 is an overall perspective view of a water purification apparatus capable of changing an operation mode in response to water quality properties according to the present invention;
Figure 2a is a flow chart of the water to be treated of the water purification apparatus according to the present invention, a flow chart when the water quality is low turbidity and low salinity;
Figure 2b is a simplified block diagram of Figure 2a;
Figure 3a is a flow chart of the water to be treated of the water treatment apparatus according to the present invention, a flow chart when the water quality property is high turbidity and low salinity;
Fig. 3b is a simplified block diagram of Fig. 3a;
Figure 4a is a flow chart of the water to be treated in the water purification apparatus according to the present invention, a flow chart when the water quality is high turbidity and high salinity;
Figure 4b is a simplified block diagram of Figure 4a;
Figure 5a is a flow chart of the water to be treated of the water purification apparatus according to the present invention, a flow chart when the water quality is low turbidity and high salinity;
Figure 5b is a simplified block diagram of Figure 5a;
Figure 6a is a flow chart showing the washing process of the reverse osmosis membrane of the water treatment apparatus according to the present invention;
Figure 6b is a simplified block diagram of Figure 6a
7 is a block diagram of a pre-processing unit according to the present invention;
8 is a block diagram of a water purification unit according to the present invention;
9 is a block diagram of a reverse osmosis unit according to the present invention;
10 is a block diagram of a sterilization unit according to the present invention;

The configuration shown in the embodiments and drawings described in this specification is only a preferred example of the disclosed invention, and there may be various modifications that can replace the embodiments and drawings of the present specification at the time of filing of the present application.

In addition, the same reference numbers or reference numerals in each drawing in the present specification indicate parts or components that perform substantially the same functions.

In addition, the terms used herein are used to describe the embodiments, and are not intended to limit and limit the disclosed invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present specification, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

In addition, terms including an ordinal number such as "first", "second", etc. used herein may be used to describe various elements, but the elements are not limited by the terms, and the terms are It is used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

Meanwhile, the terms "front", "rear", "upper", "lower", "front" and "lower" used in the following description are defined based on the drawings, and the shape of each component by this term and location is not limited.

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

1 is an overall perspective view of a water purification apparatus capable of changing an operation mode in response to water quality properties according to the present invention, and FIG. Fig. 2b is a simplified block diagram of Fig. 2a, Fig. 3a is a flow chart of the treated water of the water purification apparatus according to the present invention, a flow chart when the water quality is high turbidity and low salinity, Fig. 3b is a diagram 3a is a simplified block diagram, FIG. 4a is a flow chart of the water to be treated in the water purification apparatus according to the present invention, a flow chart when the water quality is high turbidity and high salinity, FIG. 4b is a simplified block diagram of FIG. 4a, FIG. 5a is As a flow chart of the water to be treated in the water treatment apparatus according to the present invention, the flow chart when the water quality is low turbidity and high salinity, FIG. 5B is a simplified block diagram of FIG. 5A, and FIG. 6A is reverse osmosis of the water treatment apparatus according to the present invention A flow chart showing the cleaning process of the membrane, FIG. 6B is a simplified block diagram of FIG. 6A, FIG. 7 is a configuration diagram of a pretreatment unit according to the present invention, FIG. 8 is a configuration diagram of a water purification unit according to the present invention, and FIG. According to the configuration of the reverse osmosis unit, Figure 10 is a configuration diagram of the sterilization unit according to the present invention.

Referring to the above drawing, the water treatment device 100 according to the present invention is designed to increase the water treatment efficiency by selecting and operating an operation mode suitable for the properties (turbidity and salinity) of raw water, and the pretreatment unit ( 110 ), a water purification unit 120 , a reverse osmosis unit 130 , and a sterilization unit 140 .

The pretreatment unit 110 serves to lower the turbidity of the water to be treated by a flock precipitation method, while being connected by the water to be treated inlet 10 and the first connecting pipe 20 , and is agglomerated as shown in FIG. 7 . It may be configured in detail with the group 111 and the settling tank 112 .

Here, as is well known, the agglomerator 111 mixes an Al-based coagulant with the water to be treated by a line mixer (not shown) to form flocs of colloidal particles, but to coarsen the size of the flocs. It serves to create conditions for precipitation.

In addition, a pH adjuster may be additionally added to the inside of the coagulator 111 to prevent the pH (hydrogen ion concentration index of the solution) from dropping as the coagulant is added, and agglomeration to improve the sedimentation of the flocs Auxiliaries (such as polymers) may be added.

The settling tank 112 is designed to lower the turbidity of the water to be treated by precipitating the flocs coarsened by the coagulator 111 in a short time (about 30 minutes), and the target water quality is 5NTU or less based on turbidity. can do.

The water purification unit 120 is connected to the pretreatment unit 110 and the second connection pipe 30 and removes particulate matter contained in the water to be treated. It may be configured in detail with a plurality of filtering filters 122 .

The backwash filter 121 primarily filters foreign substances of large particles contained in the water to be treated by centrifugal force as the water to be treated flows into the chamber edge of the filter housing in a whirlpool shape, and a filter element installed inside the chamber ( For example, particulate foreign matter that is not primarily filtered by the pore size of 50 μm) is secondarily filtered.

The filter filter 122 may be configured by laying gravel and sand on the lower portion of the filter housing, and filling the upper portion with filter media suitable for characteristics. In this embodiment, a multi-layer filtration filter that removes substances of 20 μm or larger, an activated carbon filter that removes odor-causing substances and organic substances, and a heavy metal filter that removes specific heavy metals (arsenic, uranium, etc.) can

The reverse osmosis unit 130 applies a pressure higher than the osmotic pressure while being connected to the water purification unit 120 and the third connecting pipe 40 to allow only pure water out of the water to be treated to pass through the separation membrane, FIG. As in 9, it may be configured in detail with the microfilter 131 and the reverse osmosis member 132 .

The micro filter 131 allows the water to be treated to pass through a cartridge filter installed inside the filter housing to filter out particles larger than 10 μm.

The reverse osmosis member 132 applies a pressure higher than the osmotic pressure of the target water flowing into the vessel to filter out ions through the semipermeable membrane and purifies the target water by passing only pure water.

The sterilization unit 140 sterilizes harmful bacteria and harmful bacteria by irradiating ultraviolet rays to the water to be treated, while being connected by the reverse osmosis unit 130 and the fourth connection pipe 50, and microbial regeneration through chlorine input. As a function of preventing, it may be subdivided into an ultraviolet sterilizer 141 for irradiating ultraviolet rays and a chlorine injector 142 for injecting chlorine as shown in FIG. 10 .

On the other hand, in the water treatment apparatus 100 according to the present invention having the above configuration, the pretreatment unit 110 , the water purification unit 120 , the reverse osmosis unit 130 and the sterilization unit 140 are configured in a modular form, and the flange joint can be interconnected by Therefore, if necessary, the flange joint part of a specific unit may be disassembled and then removed, and conversely, another unit can be expanded through the flange joint, so the configuration of the water purification apparatus 100 is variable according to the characteristics of the water purification operation. can do.

On the other hand, the water purification apparatus 100 according to the present invention may further include a bypass unit 150 for bypassing a specific module among the modules according to the turbidity and salinity of the water to be treated.

Considering that the bypass unit 150 has to pass all modules depending on the state of the water to be treated, and sometimes it is necessary to selectively pass a specific module while excluding a specific module, more efficient water purification is possible. 2a to 6b, a first bypass pipe 151 that bypasses the water to be treated inlet 10 and the water purification unit 120, and the water purification unit 120 and the sterilization unit A second bypass pipe 152 that bypasses 140, and the first connection pipe 20 or 1 A first opening/closing valve 153 for selectively opening/closing the bypass pipe 151, and a second opening/closing side 154 for selectively opening/closing a third connection pipe while installed in the third connection pipe 40; , while being installed on the second bypass pipe 152 , it may be composed of a third opening/closing valve 155 that selectively opens and closes the second bypass pipe.

Here, it goes without saying that the bypass unit 150 may be additionally installed where necessary in addition to the opening/closing valves 153 to 155 .

On the other hand, the water purification apparatus 100 according to the present invention is installed in the section between the water purification unit 120 and the sterilization unit 140, and the washing solution is injected into the vessel of the reverse osmosis unit 130 and immersed for a certain period of time. It may further include a reverse osmosis membrane cleaning member 160 for cleaning the reverse osmosis membrane installed in the vessel by the washing solution by discharging it.

The reverse osmosis membrane washing member 160 includes a washing solution storage tank 161 in which the washing solution is stored, and a washing solution supply pipe 162 connecting the outlet of the washing solution storage tank and the outlet of the third connecting pipe 40, as shown in FIG. 6b. , The contaminated water discharge pipe 163 connecting the outlet of the vessel and the washing solution storage tank 161, and the washing solution supply pipe 162 to supply the washing solution to the inside of the vessel, and after being immersed for a predetermined time, the contaminated water It may be composed of a pressure-feeding pump 164 for pressure-supplying the contaminated water to the washing liquid storage tank 161 through the discharge pipe 163 .

Hereinafter, a water purification method for selecting and operating a suitable operation mode according to the properties (turbidity and salinity) of raw water will be described. The water treatment method described herein assumes that the water treatment apparatus 100 described above is used.

1) When the water to be treated is in low turbidity/low salinity conditions (1st water purification mode: see FIGS. 2a and 2b)

In the case of the above mode, the target water introduced by blocking the first connection pipe 20 and opening the first bypass pipe 151 bypasses the pre-treatment unit 110 and is transferred to the water purification unit 120 . The water to be treated, which has passed through the water purification unit 120 by blocking the third connection pipe 40 and the second bypass pipe 152 , bypasses the reverse osmosis unit 130 to the sterilization unit. to be transferred to (140).

The first water purification mode is a mode for bypassing the pretreatment unit 110 for lowering the turbidity and the reverse osmosis unit 130 for removing salt according to the low turbidity and salinity of the water to be treated because it is not required. Accordingly, it is possible to reduce drug costs such as coagulant, pH adjuster, and coagulant aid used in the pretreatment unit 110, and it is not necessary to unnecessarily operate the high-pressure pump of the reverse osmosis unit 130, thereby reducing operating costs. there will be

2) When the water to be treated is in high turbidity/low salinity conditions (2nd water purification mode: see FIGS. 3a and 3b)

In the above mode, the first connection pipe 10 is opened and the first bypass pipe 151 is blocked so that the introduced water to be treated is transferred to the pretreatment unit 110 and the water purification unit 120, By blocking the third connection pipe 40 and opening the second bypass pipe 152 , the water to be treated that has passed through the water purification unit 120 bypasses the reverse osmosis unit 130 , and the sterilization unit 140 . to be transferred to

In the second water purification mode, because the turbidity of the water to be treated is high, it is necessary to pass through the pretreatment unit 110 to reduce the turbidity, whereas the reverse osmosis unit 130 does not need to pass through the salinity of the water to be treated because the salinity of the water to be treated is low. Accordingly, since it is not necessary to unnecessarily operate the high-pressure pump of the reverse osmosis unit 130 , it is possible to reduce operating costs.

3) When the water to be treated is in high turbidity/high salinity conditions (3rd water purification mode: see FIGS. 4a and 4b)

In the above mode, the first connection pipe 20 is opened and the first bypass pipe 151 is blocked so that the introduced water to be treated passes sequentially through the pretreatment unit 110 and the water purification unit 120 . and opening the third connection pipe 40 and blocking the second bypass pipe 152 so that the water to be treated that has passed through the water purification unit 120 has the reverse osmosis unit 130 and the sterilization unit 140 . to pass sequentially. Therefore, the driving is carried out via all sections.

In the third water purification mode, since the turbidity and salinity of the water to be treated is high, it must pass through the pretreatment unit 110 and the reverse osmosis unit 130 .

4) When the water to be treated is in low turbidity/high salinity conditions (4th water purification mode: see FIGS. 5a and 5b)

In the case of the above mode, the target water introduced by blocking the first connection pipe 20 and opening the first bypass pipe 151 bypasses the pre-treatment unit 110 and is transferred to the water purification unit 120 . The water to be treated, which has passed through the water purification unit 120 by opening the third connection pipe 40 and blocking the second bypass pipe 152 , is the reverse osmosis unit 130 and the sterilization unit 140 . ) are passed sequentially.

In the fourth water purification mode, the pretreatment unit 110 does not need to pass through because the turbidity of the water to be treated is low, whereas the reverse osmosis unit 130 must pass through because the salinity of the water to be treated is high. Accordingly, it is possible to reduce the cost of drugs used in the pretreatment unit 110 , such as a coagulant, a pH adjuster, and a coagulation aid.

On the other hand, in order to wash the reverse osmosis membrane installed inside the vessel of the reverse osmosis unit 130, the following process is performed.

That is, as shown in FIGS. 6A and 6B , in a state in which the introduction of the water to be treated is stopped, the pressure pump 164 is operated to transfer the washing solution in the washing solution storage tank 161 through the washing solution supply pipe 162 to the reverse osmosis unit (130) to be supplied to the inside of the vessel.

Next, the operation of the pressure pump 164 is stopped so that the reverse osmosis membrane is immersed in the washing solution supplied to the inside of the vessel for a set time to remove foreign substances attached to the reverse osmosis membrane.

Next, when the set time elapses, the pressure pump 164 is restarted to recover the contaminated water contaminated by the washing inside the vessel to the washing solution storage tank 161 through the contaminated water discharge pipe 163. rough

Thereafter, the contaminated water collected in the washing solution storage tank 161 is drained to the outside and discharged.

Although the above-described embodiment has been described with respect to a preferred embodiment of the present invention, the present invention is not limited thereto, and it is specified that it can be implemented by changing it in various forms without departing from the technical spirit of the present invention.

100: water treatment device 110: pre-treatment unit
111: coagulant 112: settling tank
120: water purification unit 121: backwash filter
122: filtration filter 130: reverse osmosis unit
131: micro filter 132: reverse osmosis filter
140: sterilization unit 141: ultraviolet sterilizer
142: chlorine injector 150: bypass unit
151: first bypass tube 152: second bypass tube
153: first opening and closing valve 154: second opening and closing valve
155: third opening and closing valve 160: reverse osmosis three chin member
161: washing liquid storage tank 162: washing liquid supply pipe
163: polluted water discharge pipe 164: pressure pump

Claims (8)

a pre-treatment unit for lowering the turbidity of the water to be treated by a flock precipitation method, while being connected to the treatment water inlet and the first connection pipe; a water purification unit for removing particulate matter contained in the water to be treated while being connected to the pretreatment unit by a second connection pipe; a reverse osmosis unit that applies a pressure higher than the osmotic pressure while being connected to the water purification unit and the third connecting pipe to allow only pure water, of the water to be treated, to pass through the separation membrane; and a sterilization unit that sterilizes harmful bacteria and harmful bacteria by irradiating ultraviolet rays to the water to be treated, while being connected to the reverse osmosis unit and the fourth connection pipe, and preventing re-reproduction of microorganisms by introducing chlorine. Further comprising a bypass unit for bypassing a specific unit among the units according to the turbidity and salinity of the water,
The bypass unit may include: a first bypass pipe that bypasses the water to be treated inlet and the water purification unit; a second bypass pipe that bypasses the water purification unit and the sterilization unit; a first opening/closing valve that selectively opens and closes the first connection pipe or the first bypass pipe while being installed at a branch point between the target water introduction part and the first bypass pipe; a second opening/closing valve for selectively opening and closing the third connecting pipe while being installed in the third connecting pipe; and a third opening/closing valve configured to selectively open and close the second bypass pipe while being installed in the second bypass pipe;
The pretreatment unit includes a condenser and a settling tank, the water purification unit includes a backwash filter and a plurality of filtration filters, the reverse osmosis unit includes a microfilter and a reverse osmosis member, and the sterilization unit includes an ultraviolet sterilization lamp and chlorine Further comprising an injection member,
Each component of the pretreatment unit, the water purification unit, the reverse osmosis unit and the sterilization unit is configured in a modular type, and further comprising that it is installed horizontally by a flange joint,
Reverse osmosis membrane cleaning member installed in the section between the water purification unit and the sterilization unit, injecting the washing solution into the vessel of the reverse osmosis unit, immersing it for a certain time, and then discharging the reverse osmosis membrane installed in the vessel to be washed by the washing solution,
The reverse osmosis membrane washing member may include a washing solution storage tank; a washing solution supply pipe connecting the outlet of the washing solution storage tank and the outlet of the third connecting pipe; a contaminated water discharge pipe connecting the outlet of the vessel and the washing solution storage tank; and a pressure pump that supplies the washing solution to the inside of the vessel through the washing solution supply pipe, and pumps the contaminated water to the washing solution storage tank through the contaminated water discharge pipe after the reverse osmosis membrane inside the vessel is immersed for a certain period of time. It is a water purification method using a water treatment device that can change the operation mode according to the quality of the water to be used.
When the water quality of the water to be treated introduced through the treatment water introduction part is in the low turbidity and low salinity conditions, the first connection pipe is blocked and the target water introduced by opening the first bypass pipe is the pre-treatment Bypassing the unit and transferring it to the water purification unit, blocking the third connection tube and opening the second bypass tube so that the water to be treated that has passed through the water purification unit bypasses the reverse osmosis unit and is transferred to the sterilization unit The first water purification mode is executed,
When the water quality of the water to be treated introduced through the treatment water introduction unit is in high turbidity and low salinity conditions, the first connection pipe is opened and the first bypass pipe is blocked and the treated water introduced into the pretreatment unit The second purified water is transferred to the water purification unit and the third connecting pipe is blocked and the second bypass pipe is opened so that the water to be treated that has passed through the water purification unit bypasses the reverse osmosis unit and is transferred to the sterilization unit. the mod is running,
When the water quality of the water to be treated introduced through the treatment water introduction unit is in high turbidity and high salinity conditions, the first connection pipe is opened and the first bypass pipe is blocked and the treated water introduced into the pretreatment unit and the water purification unit sequentially, and the third connection pipe is opened and the second bypass pipe is blocked so that the to-be-treated water passing through the water purification unit passes through the reverse osmosis unit and the sterilization unit sequentially. 3 Water purification mode is executed,
When the water quality of the water to be treated introduced through the treatment water introduction part is in low turbidity and high salinity conditions, the first connection pipe is blocked and the target water introduced by opening the first bypass pipe is the pre-treatment Bypassing the unit and transferring it to the water purification unit, opening the third connection tube and blocking the second bypass tube so that the treated water passing through the water purification unit passes through the reverse osmosis unit and the sterilization unit sequentially A purified water treatment method in which a fourth water purification mode is executed.
delete delete delete delete delete delete The method according to claim 1,
For cleaning the reverse osmosis membrane installed inside the vessel of the reverse osmosis unit,
In a state in which the introduction of the target water is stopped, the pressure pump is operated to supply the washing solution in the washing solution storage tank to the inside of the vessel of the reverse osmosis unit through the washing solution supply pipe,
Stop the operation of the pressure pump to keep the reverse osmosis membrane immersed in the washing solution supplied to the inside of the vessel for a set time to remove foreign substances attached to the reverse osmosis membrane,
When the set time elapses, the pressure pump is restarted to recover the contaminated water contaminated by washing inside the vessel to the washing solution storage tank through the contaminated water discharge pipe.

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