KR20140009945A - Water treatment apparatus - Google Patents

Abstract

The purpose of the present invention is to provide a water treatment apparatus capable of improving sterilization efficiency thereof while minimizing the waste of water by generating sterilized water using wastewater being discharged from a reverse osmosis membrane filter. The water treatment apparatus according to the present invention comprises a filter part including a reverse osmosis membrane filter for filtering raw water; a storage part including a first storage tank and a second storage tank for storing water filtered by the filter part at different temperatures which are interconnected via a connection line; a wastewater supply line for supplying wastewater generated by the reverse osmosis membrane filter to the first storage tank; and a sterilization module installed on a channel connected to the wastewater supply line to supply sterilized water to the storage part. [Reference numerals] (AA) Raw water

Description

[0001] WATER TREATMENT APPARATUS [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water treatment apparatus, and more particularly, to a water treatment apparatus capable of sterilizing a water tank and a pipe using sterile water.

As water pollution due to industrial development becomes serious, distrust in tap water increases, and recently, purified water with a water purifier is used as drinking water or commercially available bottled water as drinking water.

The water purifier is made to remove heavy metals and other harmful substances contained in the raw water through the process of sedimentation, filtration, sterilization, and adsorption of raw water such as tap water, and the like. It is also widely used for cleaning or medical use of high precision electronic components.

Conventional water purifiers include a raw water valve for controlling the supply of raw water such as tap water and natural water, a pretreatment sedimentation filter for filtering the residue in the raw water that has passed through the raw water valve, and for moving the supplied raw water to a predetermined pressure. A pressurized pump, a pre-carbon filter for removing chlorine components and odors in raw water, a reverse osmosis membrane filter for removing ionic heavy metals remaining in raw water passing through the pre-carbon filter, and the reverse osmosis membrane filter A wastewater regulator for discharging wastewater by adjusting the ratio of purified water to wastewater passing through the raw water, a post carbon filter for removing chlorine or odor contained in the purified water passed through the reverse osmosis membrane filter, and the post carbon filter. It consists of a water tank for storing the purified water.

Generally, chlorine-based disinfectants are administered in water treatment plants to suppress the growth of microorganisms in water. Some of the chlorine components are removed from the pre-carbon filter while the tap water to which the disinfectant is administered passes through the water purifier and is ionic in the reverse osmosis membrane filter. Chlorine is removed and stored in the water tank.

Since the chlorine component that suppresses the growth of microorganisms is removed by the filter, the purified water stored in the water tank is not used immediately by the consumer, and bacteria proliferate inside the water tank after a long time elapses Various methods have been proposed for the sterilization of these water tanks.

For example, the Republic of Korea Patent No. 10-621937 discloses a technique for sterilizing the interior of the purified water tank by having an electrolytic sterilization means for generating a sterilization and oxidizing mixture of purified water by electrolysis between the filter portion and the purified water tank, According to this configuration, since the dissolved ionic substances contained in the raw water are removed while passing through the filter unit, a sufficient amount of sterilizing substance may not be generated during the passage of the electrolytic sterilization means, which causes a problem of lowering sterilization efficiency.

In addition, the filter unit may be equipped with a reverse osmosis membrane filter. In general, the amount of purified water in the raw water obtained by the reverse osmosis membrane filter and the amount of water discharged into the waste water is 2: 8.

The present invention has been made to solve the above-mentioned problems, to provide a water treatment apparatus that can minimize the waste of water and improve sterilization efficiency by generating sterilization water using wastewater discarded in the reverse osmosis membrane filter. The purpose is to.

Water treatment device of the present invention for achieving the above object, the filter unit including a reverse osmosis membrane filter to filter the raw water; A storage unit for storing the water filtered in the filter unit at different temperatures and including a first storage tank and a second storage tank interconnected by connection lines; A wastewater supply line configured to supply the wastewater generated by the reverse osmosis membrane filter to the first storage tank; Is installed on the flow path connected to the waste water supply line is composed of a sterilization module for supplying sterilization water to the storage.

The wastewater supply line may be branched from the wastewater drainage line for discharging wastewater generated by the reverse osmosis membrane filter to the outside and connected to the connection line.

The first storage tank, an upper space for storing the filtered water at a room temperature state, and a separation plate is installed between the upper space and the lower space for storing cold water, and the upper space extending downward from the separation plate A connecting flow passage crossing the lower space such that the water passes through the inside of the lower space without being mixed with water in the lower space and is supplied to the second storage tank through the connecting line; The sterilization module may be installed on a connection line connected to the lower side of the connection flow path.

A circulation line branched from the connection line and interconnected between the first storage tanks is provided, and for circulating the sterilizing water in the first storage tank through the connection line and the circulation line back into the first storage tank. A circulation pump may be provided.

On the circulation line, a shutoff valve may be provided to block water from the lower space of the first storage tank from flowing into the second storage tank when the purified water filtered through the filter part is supplied to the first storage tank.

A wastewater supply valve is installed on the wastewater supply line to control whether wastewater is supplied to the first storage tank, and on the connection line, the wastewater is supplied only to the first storage tank, and the wastewater is introduced into the second storage tank. Shut off valve may be provided to block.

The sterilization module may be operated in a state in which water flows into the first storage tank or blocks water from flowing out of the first storage tank.

A first drain line and a second drain line for draining sterilized water filled therein may be connected to the first storage tank and the second storage tank, respectively.

According to the present invention, the waste water generated by using the wastewater generated in the reverse osmosis membrane filter can be minimized, and the waste of discarded water can be minimized. The efficiency can be improved.

In addition, when the sterilization module is installed in front of the reverse osmosis membrane filter, the sterilization material generated in the sterilization module sterilizes the bacteria grown on the filter membrane of the reverse osmosis membrane filter, thereby providing clean water to the user.

In addition, the drainage line for draining sterilization water is branched right before the intake valve installed on the intake line for supplying purified water to the user and drained to the outside. The area of the dead zone that is not sterilized can be minimized.

1 is a view showing a configuration of a water treatment apparatus according to a first embodiment of the present invention,
2 is a view showing an operating state when draining in the water treatment apparatus according to the first embodiment of the present invention,
3 is a view showing a sterilizing water inflow process in the water treatment apparatus according to the first embodiment of the present invention,
4 is a view showing a sterilization water draining process in the water treatment apparatus according to the first embodiment of the present invention;
5 is a view showing an operating state when rinsing in the water treatment apparatus according to the first embodiment of the present invention,
6 is a view showing an operating state when rinsing water drainage in the water treatment apparatus according to the first embodiment of the present invention,
7 is a view showing an operating state when the purified water inflow in the water treatment apparatus according to the first embodiment of the present invention,
8 is a view showing the configuration of a water treatment apparatus according to a second embodiment of the present invention;
9 is a view showing the configuration of a water treatment apparatus according to a third embodiment of the present invention,
10 is a view showing the configuration of a water treatment device according to a fourth embodiment of the present invention;
11 is a view showing the configuration of a water treatment device according to a fifth embodiment of the present invention;
12 is a view showing the configuration of a water treatment device according to a sixth embodiment of the present invention;
13 is a view showing an operating state when draining in the water treatment apparatus according to a sixth embodiment of the present invention,
14 is a view showing a wastewater inflow process in a water treatment device according to a sixth embodiment of the present invention;
15 is a view showing a sterilizing water generation process in a water treatment device according to a sixth embodiment of the present invention;
16 is a view showing a sterilized water drainage process in the water treatment apparatus according to the sixth embodiment of the present invention,
17 is a view showing a rinsing water inflow process in the water treatment apparatus according to a sixth embodiment of the present invention,
18 is a view showing the configuration of a water treatment device according to a seventh embodiment of the present invention;
19 is a configuration diagram for measuring the residual chlorine concentration according to the installation position of the sterilization module in the water treatment apparatus of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

≪ Embodiment 1 >

1 is a view showing the configuration of a water treatment apparatus according to a first embodiment of the present invention.

The water treatment apparatus according to the first embodiment of the present invention includes a filter unit 100 composed of a plurality of filters 110, 120, 130 and 140 for filtering raw water, a storage unit 200 for storing the filtered water in the filter unit 100, A sterilizing module 300 for supplying sterilizing water to the storage 200, a water intake 400 for taking water stored in the storage 200 to the user, And a drainage unit 500 for draining sterilized water to the outside.

The filter unit 100 passes through a pre-treatment sedimentation filter 110 that filters waste in raw water, a pre-carbon filter 120 for removing chlorine components and odors in raw water, and the pre-carbon filter 120. Reverse osmosis membrane filter 130 for removing ionic heavy metal remaining in the raw water, and post carbon filter 140 for removing chlorine components or odor contained in the purified water passed through the reverse osmosis membrane filter 130 It may be made of.

The reverse osmosis membrane filter 130 and the post-carbon filter 140 may be reversed with each other, and the pressure pump for supplying the raw water supplied to the reverse osmosis membrane filter 130 at a predetermined pressure (Fig. Not shown) may be provided.

Each of the filters (110, 120, 130, 140) is interconnected by a plurality of pipes (601, 602, 603) to form a raw water supply line for moving the raw water, and pipes for connecting between the pre-treatment precipitation filter 110 and the pre-carbon filter (120) ( The raw water valve 150 may be provided on the 601 to control the inflow of raw water.

The raw water valve 150 may be installed at the inlet side of the pretreatment sedimentation filter 110, but since the raw water contains a large amount of foreign substances, when the raw water flows directly into the raw water valve 150, the durability of the raw water valve 150 may be reduced. Since it may fall, it is preferable to pass the raw water valve 150 after the first filtering the foreign matter contained in the raw water in the pre-treatment settling filter 110.

The reverse osmosis membrane filter 130, an inlet 131 through which the raw water passed through the pre-carbon filter 120 is introduced, and a purified water outlet 132 through which water filtered by an internal filter member (not shown) is discharged. And a wastewater discharge port 133 through which the wastewater not filtered by the filter member is discharged.

Since the ratio of the wastewater discharged through the wastewater discharge port 133 and the purified water discharged through the purified water discharge port 132 is about 8: 2, separation of wastewater from the purified water on the wastewater drainage line 611 to reduce the amount of waste water. Wastewater regulator 540 for adjusting the ratio is provided. The wastewater regulator 540 may be configured to block a portion of the passage through which water flows in order to limit the amount of water passing through the wastewater drainage line 611 within a predetermined range.

The storage unit 200 is for storing the water filtered by the filter unit 100, the first storage tank 210 for storing cold water and purified water, and the first storage by the connection line 621. The second storage tank 220 is connected to the tank 210 to store hot water.

The first storage tank 210 has a water level sensor 211 for sensing the water level inside the tank to control the supply of water introduced into the tank, the water introduced into the tank when the water level sensor 211 is malfunctioning Ball tower 212 for blocking the separation plate 213, the separation plate 213 for separating the internal space of the tank into the upper space 210a, where the purified water at room temperature is stored and the lower space 210b, the cold water is stored. Extending downward from the center of the lower space 210b to be connected to the second storage tank 220 to supply the purified water to the second storage tank 220 without being mixed with cold water. A connection passage 214 is provided.

When the water level sensor 211 detects that the water level in the first storage tank 210 is a full water level, the raw water valve 150 is turned off to block the supply of raw water, and the balltop 212 is the water level. When the sensor 211 is broken, the inlet through which water is introduced into the first storage tank 210 is blocked at a level higher than the water level sensor 211.

In the present embodiment, it is assumed that both the water level sensor 211 and the ball top 212 are provided, but only the water level sensor 211 or the ball top 212 is provided to control the water level inside the first storage tank 210. It can also be configured as.

One end of the connection line 621 is connected to the first storage tank 210 to be connected to the connection flow path 214, the other end is connected to the second storage tank 220, the filter unit 100 The purified water supplied through is supplied to the second storage tank 220 through the connection line 621 as well as the first storage tank 210.

A cooling coil (not shown) for cooling purified water stored in the lower space 210b is provided on the outer circumference of the lower space 210b. A heater for heating the purified water stored in the outer circumference of the second storage tank 220 Not shown). Of course, the cooling coil and the heater may be provided in the lower space 210b of the first storage tank 210 and the second storage tank 220.

A purified water supply line 604 for supplying purified water and a sterilized water supply line 612 for supplying sterilized water are installed between the filter unit 100 and the storage 200, and the sterilized water supply line 612 is provided. The sterilization module 300 for supplying sterilization water to the storage unit 200 is installed on the).

The purified water supply line 604 has one end connected to the post carbon filter 140 and the other end connected to the ball top 212 of the first storage tank 210. When the water level sensor 211 fails, the purified water The supply of purified water and sterilizing water supplied through the supply line 604 is controlled by one ball tower 212.

The sterilization module 300, for example, by electrolyzing water to react with chlorine ions and hydrogen, oxygen, etc. contained in the raw water to generate sterilization materials such as HOCl, ClO ^- ions, positive electrode (not shown) And a negative electrode (not shown), and the positive electrode and the negative electrode may be configured to be supplied with power by a power supply (not shown in the figure), the electrode may be coated with platinum or iridium.

The sterilizing water supply line 612 is configured such that one end thereof is branched from the wastewater drainage line 611 and the other end thereof is connected to the first storage tank 210, so as to discharge the wastewater outlet of the reverse osmosis membrane filter 130. The wastewater discharged through 133 may be supplied to the sterilization module 300 through the sterilization water supply line 612 to generate sterilization water and supply the generated sterilization water to the first storage tank 210.

Wastewater discharged through the wastewater outlet 133 is concentrated water that is not filtered through the reverse osmosis membrane filter 130, and the concentrated water includes dissolved ionic substances (Cl-; chlorine ions) included in the raw water. It is contained at a higher concentration than purified water, so when the electrolysis when passing through the sterilization module 300 can generate more sterilizing material than electrolysis using raw water or purified water can improve sterilization efficiency In addition, since waste water is used as waste water, waste of waste water can be minimized.

A sterilization water supply valve 310 is installed on the sterilization water supply line 612 to control whether water is supplied to the sterilization module 300, and the sterilization water supply line 612 is combined with the purified water supply line 604. Is connected to the ball top 212 of the first storage tank 210. As such, when the purified water supply line 604 and the sterilizing water supply line 612 are combined to be connected to the ball top 212 of the first storage tank 210, the water level sensor 211 or the sterilizing water supply valve 310 is provided. In case of failure), not only the purified water flows into the first storage tank 210 but also the sterilized water is filled into the first storage tank 210 by a predetermined level or more even when the sterilized water flows into the first storage tank 210. Can be blocked, simplifying configuration.

In this embodiment, the configuration in which the purified water supply line 604 and the sterilized water supply line 612 are combined into one, but the purified water supply line 604 is connected to the ball tower 212 and the sterilized water supply line 612 May be configured to be directly connected to the first storage tank 210 without a mechanical shutoff device such as the ball top 212. In this case, the level control of the sterilizing water filled in the first storage tank 210 is made of the water level sensor 211 only.

The water stored in the first storage tank 210 and the second storage tank 220 is supplied to the user through the water intake unit 400. The intake unit 400 is installed on the first intake line 631 connected to the lower space 210b of the first storage tank 210, the first intake valve 410 for regulating the supply of cold water, and The second intake valve 420 is installed on the second intake line 632 connected to the second storage tank 220 to regulate the supply of hot water.

The drainage part 500 controls the discharge rate of the wastewater discharged from the reverse osmosis membrane filter 130 by the wastewater regulator 540 and then drains the wastewater to the outside through the wastewater drainage line 611 as well as the first storage. After sterilizing and filling the sterilizing water into the tank 210 and the second storage tank 220, the sterilizing water is drained to the outside.

In order to drain the sterilizing water in the first storage tank 210 to the outside, the first draining line 641 branched from the first intake line 631 and the second sterilizing water in the second storage tank 220 to the outside. A second drain line 642 is provided for drainage, and two drain valves 510 and 520 are provided for controlling sterilizing water drained through the first drain line 641 and the second drain line 642. .

Although there is a problem in that the purified water is contaminated inside the first intake line 631 located in front of the first intake valve 410, contaminated by bacteria, In the present invention, the first drain line 641 is branched on the first intake line 631 immediately before the first intake valve 410 to sterilize even the inside of the first intake line 631 using sterilized water that is drained. can do.

The drainage of the sterilization water through the drainage lines 641 and 642 may be a natural drainage using the head difference, and when the drainage pump 530 is installed as in this embodiment, the drainage time is shortened by smoothly draining the sterilization water. can do.

The drain pump 530 is a voltage / current is changed according to the change in the amount of water passing through the inside, that is, the load, load variation detection unit for detecting the change in the voltage / current (not shown) It can be configured to determine whether the drainage of purified or sterilized water is completed.

Since the sterilization mode according to the first embodiment of the present invention is performed in the order of drainage → sterilization water inflow → sterilization water drain → rinsing water inflow → rinsing water drain → water purification inflow, the first embodiment will now be described with reference to FIGS. 2 to 7. The sterilization effect of the water treatment apparatus according to the example will be described.

2 is a view showing an operating state when draining in the water treatment apparatus according to the first embodiment of the present invention, Figure 3 is a view showing a sterilizing water inflow process in the water treatment apparatus according to the first embodiment of the present invention, Figure 4 5 is a view illustrating a sterilization water draining process in a water treatment apparatus according to a first embodiment of the present invention, FIG. 5 is a view showing an operating state when rinsing in a water treatment apparatus according to the first embodiment of the present invention, and FIG. 6 is a first view of the present invention. 7 is a view illustrating an operating state when rinsing water is drained in the water treatment apparatus according to the embodiment, and FIG. 7 is a view showing an operating state of water purification in the water treatment apparatus according to the first embodiment of the present invention.

When the sterilization mode is activated, first, as shown in FIG. 2, the raw water valve 150, the sterilization module 300, and the sterilization water supply valve 310 are in an off state, and the first drain valve 510 and the second drain are discharged. The drain valve 520 drains all of the water in the first storage tank 210 and the second storage tank 220 by operating the drain pump 530 in the on state, and when the drainage is completed, the first drain valve 510, the second drain valve 520, and the drain pump 530 are all in an off state.

Here, Off means a state in which the valves 150, 310, 510, 520 are closed or the state in which the sterilization module 300 and the drain pump 530 are not operated. On means the state in which the valves 150, 310, 510, 520 are open or the sterilization module. Means the state in which the 300 and the drain pump 530 is operated, the same meaning also in the case of other embodiments described later.

In this case, whether the water of the first storage tank 210 and the second storage tank 220 is drained, the load variation detection unit detects a change in voltage / current and receives the detected signal to switch to the next step. It can be configured as.

When the drainage is completed as described above, the sterilizing water inflow process is performed. As shown in FIG. 3, the first drain valve 510, the second drain valve 520, and the drain pump 530 are in an off state, raw water. When the valve 150, the sterilizing water supply valve 310, and the sterilizing module 300 are turned on, the purified water filtered by the reverse osmosis membrane filter 130 passes through the first carbon tank 140 through the post carbon filter 140. Some of the wastewater introduced into the 210 and not filtered by the reverse osmosis membrane filter 130 is discharged to the outside through the wastewater regulator 540 and the wastewater drainage line 611, and the rest is sterilized water supply line 612. Supplied to the sterilization module 300 through, the electrolysis of the waste water passing through the sterilization module 300, such as hypochlorous acid (HClO), hypochlorous acid (OCl-), chlorine (Cl ₂ ) Is generated and flows into the first storage tank 210 and the second storage tank 220.

The amount of wastewater drained through the wastewater drainage line 611 is controlled by the wastewater regulator 540 and then only a very small amount is drained, and most of the remaining wastewater is supplied to the sterilization module 300 through the sterilization water supply line 612. When the electrolyzed wastewater supplied to the sterilization module 300 is promoted the generation of sterilization material to improve the sterilization effect, it is possible to recycle the wastewater discarded, thereby reducing the material source.

That is, since the chlorine component is removed from the pre-carbon filter 120 and the post carbon filter 140, and the chlorine ion (Cl ⁻ ), which is an ionic substance, is removed from the reverse osmosis membrane filter 130, through the filter unit 100. In the case of generating sterilized water in the sterilization module 300 using the filtered purified water, since the concentration of the sterilizing material may be low, in the present invention, the sterilizing water is used by using the waste water which is the concentrated water having a higher concentration of the ionic material than the raw water. To produce.

In this case, the first storage tank 210 and the second storage tank 220 is supplied with purified water through the purified water supply line 604 as well as sterilized water, wastewater supplied to the sterilization module 300 is compared to the raw water Since the sterilized water is generated in a concentration of about 1.2 to 1.5 times higher than that of the sterilized water generated by using the raw water because the concentrated water contains a large amount of ionic substances, the purified water supplied through the purified water supply line 604 is mixed. Even if the sterilizing material concentration of the sterilizing water supplied through the sterilizing water supply line 612 is high, the sterilizing function can be sufficiently performed.

In addition, in the prior art, it was difficult to sterilize the inside of the first intake line 631, but in the present invention, since the sterilization water is filled in the first intake line 631 at the front end where the first intake valve 410 is installed, sterilization is performed. It is possible to minimize the generation zone of the dead zone that is not sterilized in the water treatment apparatus.

The sterilizing water introduced into the first storage tank 210 is also filled in the second storage tank 220 through the connection line 621, and the water level of the first storage tank 210 and the second storage tank 220. When the water level sensor 211 detects that the water level is full, the raw water valve 150, the sterilization module 300, and the sterilization water supply valve 310 are turned off and are sterilized by sterilizing water for a predetermined time. Work is done.

After sterilization is performed by the above process, the sterilization water in the first storage tank 210 and the second storage tank 220 is drained, as shown in FIG. 4, the raw water valve 150 and the sterilization module. 300 and the sterilizing water supply valve 310 maintains an off state and operates the drain pump 530 in a state in which the first drain valve 510 and the second drain valve 520 are turned on. Operated to drain the sterilized water in the first storage tank 210 and the second storage tank 220 to the outside through the waste water drainage line 611 through the first drain line 641 and the second drain line 642. Let's do it.

As such, when the drainage of the sterilization water is completed, a rinsing process is performed to wash the sterilization water remaining in the first storage tank 210 and the second storage tank 220. As shown in FIG. The source water valve 150 is turned on while the sterilizing water supply valve 310, the first drain valve 510, the second drain valve 520, and the drain pump 530 are all turned off. When the raw water is filtered through the filter unit 100, the filtered water (hereinafter referred to as 'rinsing water') is the first storage tank 210 and the second storage tank 220 through the purified water supply line 604. Flows into).

Although the rinsing water is introduced into the first storage tank 210 only through the purified water supply line 604, the rinsing water passes through the reverse osmosis membrane filter 130 to allow the rinsing water to flow into the first storage tank 210. There is a problem that takes a long time to fill up to the full water level.

Therefore, when only the sterilization water supply valve 310 of the sterilization water supply line 612 and the sterilization module 300 is off, the raw water valve 150 is turned on, and the rinsing water is purified. Since it is simultaneously supplied through the supply line 604 and the sterilization water supply line 612 it can save the time required for the supply of the rinsing water. In this case, if a separate filter (not shown in the drawing) is configured on the sterilizing water supply line 612, water from which suspended substances which may be included in the waste water may be used as the rinsing water, thereby further increasing the rinsing effect. .

When the rinsing water is filled up to the full water level of the first storage tank 210 and the second storage tank 220, the rinsing water is drained, as shown in FIG. 6, the raw water valve 150 and the sterilizing water supply valve 310. ) And the sterilization module 300 is turned off, and the first drain valve 510, the second drain valve 520, and the drain pump 530 are turned on, and the rinsing water is drained. Drain to the outside via line 611. In this case, after the rinsing water is filled up to the full water level and a predetermined time has elapsed, the rinsing water can be drained to further improve the rinsing effect.

When the drainage of the rinsing water is completed, as shown in FIG. 7, the sterilization water supply valve 310, the sterilization module 300, the first drain valve 510, the second drain valve 520, and the drain pump 530. When the raw water valve 150 is turned on in the off state, the raw water is filtered through the filter unit 100 and then filled in the first storage tank 210 and the second storage tank 220. Sterilization mode is terminated.

On the other hand, the completion point of the drainage may be configured to detect that the drainage is completed by detecting the difference in voltage / current in the drainage pump 530, as described above, may be set for a time to drain for a predetermined time, It is also possible to configure a separate sensor such as an infrared sensor to determine the completion point of the drainage.

The sterilization mode as described above may be set to be automatically repeated at regular intervals, or may be configured to be performed by a user's selection.

≪ Embodiment 2 >

8 is a view showing the configuration of the water treatment apparatus according to the second embodiment of the present invention. All the constitutions are the same as the water treatment apparatus according to the first embodiment, and the purified water shutoff valve 320 is provided on the purified water supply line 604, Is further provided.

The purified water shutoff valve 320 is for controlling the supply of purified water passing through the purified water supply line 604, the sterilization module 300 is operated to the first storage tank 210 and the second storage tank 220 In the case of supplying sterilized water to the purified water cutoff valve 320, the supply of purified water is cut off through the purified water supply line 604, and the first storage tank only through the sterilized water supply line 612. Since the sterilizing water is supplied to the 210 and the second storage tank 220, the sterilizing material concentration of the sterilizing water is increased to improve the sterilizing effect.

Third Embodiment

9 is a view showing the configuration of a water treatment device according to a third embodiment of the present invention, all the configuration is the same as the water treatment device according to the first embodiment, the cold water and hot water supplied through three water intake lines (631, 632, 633) And the purified water is characterized in that it is supplied to the user through one inlet 440.

That is, the first intake line 631, the second intake line 632, and the third intake line 633 include the first intake valve 410, the second intake valve 420, and the third intake valve 430. Each of the three intake lines 631, 632, and 633 are combined into one intake port 440 to supply cold water, hot water, and purified water through one intake port 440.

At the points where the three intake lines 631, 632 and 633 meet, the inlet 440 and the first flow path of the water supplied through the first intake valve 410, the second intake valve 420, and the third intake valve 430. A flow path switching valve 550 for switching to any one of the drain lines 641 is installed.

The flow path switching valve 550 is set in the open direction of the valve so that the flow path on the intake port 440 side in the purified water mode, the sterilization mode is activated to the first storage tank 210 and the second storage tank 220 When draining the filled sterilized water to direct the drainage direction of the sterilized water drained through the first intake line 631 and the second intake line 632 and the third intake line 633 toward the first drain line 641 side. It is switched to block the intake port 440 side and open the flow path of the first drain line 641.

<Fourth Embodiment>

10 is a view showing the configuration of a water treatment device according to a fourth embodiment of the present invention, all configurations are the same as the water treatment device according to the first embodiment, the sterilization module 300 of the reverse osmosis membrane filter 130 It is characterized in that the inlet 131 is provided in front and three intake lines (631, 632, 633), one intake port 440 and the flow path switching valve 550.

When the sterilization mode is activated, the water filtered by the pretreatment carbon filter 120 is passed through the sterilization module 300, the sterilization water is generated and introduced into the reverse osmosis membrane filter 130, the pores of the membrane of the reverse osmosis membrane filter 130 Since the diameter is 0.0001 μm and does not penetrate to the ionic component in the raw water, the sterilizing substance, which is an ionic component included in the sterilizing water, does not pass through the membrane of the reverse osmosis membrane filter 130 and is sterilized water supply line through the wastewater outlet 133. The purified water passing through the membrane of the reverse osmosis membrane filter 130 through the purified water supply line 604 is introduced into the first storage tank 210 through the 612, the first storage tank 210. The sterilizing water supply valve 310 is installed on the sterilizing water supply line 612 to control whether the sterilizing water is supplied.

Thus, even if the sterilization module 300 is installed in the front end of the inlet 131 of the reverse osmosis membrane filter 130 according to the experimental results described below the residual chlorine concentration of the sterilization water supplied through the sterilization water supply line 612 is a sterilization function It can be confirmed that the degree is sufficient to perform the operation.

Further, if the water treatment apparatus is not used for a predetermined period of time, bacteria will multiply on the filter membrane of the reverse osmosis membrane filter 130. When the sterilizing module 300 is installed on the upstream side of the reverse osmosis membrane filter 130 as described above The germicidal material generated in the sterilization module 300 may be introduced into the reverse osmosis membrane filter 130 to sterilize the filter membrane while being in contact with the filter membrane, thereby providing more clean water to the user.

In the above, an embodiment in which one intake port 440 and a flow path switching valve 550 are provided has been described. However, the first intake valve 510 and the same drainage valve 510 are configured in a plurality of intake ports as in the first embodiment. It is possible to implement.

<Fifth Embodiment>

11 is a view showing the configuration of a water treatment device according to a fifth embodiment of the present invention, all configurations are the same as the water treatment device according to the first embodiment, the sterilization module 300 of the reverse osmosis membrane filter 130 It is characterized by being installed at the front end.

Inlet 131 of the reverse osmosis membrane filter 130, the raw water supply line 602 connected to the outlet of the pre-carbon filter 120, the raw water filtered by the pre-carbon filter 120 flows, and the sterilization module The sterilizing water line 605 in which the 300 and the sterilizing water supply valve 330 are installed is connected in parallel.

In addition, the sterilization water supply valve (330) on the sterilization water supply line 612 connected to the wastewater outlet 133 of the reverse osmosis membrane filter 130 separately from the sterilization water supply valve 330 installed at the inlet side of the sterilization module 300 ( 310 is installed.

When the first storage tank 210 and the second storage tank 220 is filled with purified water, the raw water valve 150 is turned on in a state in which the sterilization module 300 and the sterilization water supply valves 310 and 330 are turned off. On) so that the raw water flows into the first storage tank 210 and the second storage tank 220 through the filter unit 100.

Meanwhile, when the sterilization mode is activated, the raw water valve 150 is turned off to block the flow path into the pre-carbon filter 120, and the sterilization water supply valves 310 and 330 and the sterilization module 300 are turned on. The water passing through the pretreatment precipitation filter 110 passes through the sterilization module 300 to generate sterilization water so as to flow into the inlet 130 of the reverse osmosis membrane filter 130.

Since the pore diameter of the membrane of the reverse osmosis membrane filter 130 is 0.0001 μm and does not permeate to the ionic component of raw water, the sterilizing material introduced into the reverse osmosis membrane filter 130 is a filter of the reverse osmosis membrane membrane filter 130. The purified water, which does not pass through the membrane, enters the first storage tank 210 through the sterilizing water supply line 612, and passes through the filter membrane of the reverse osmosis membrane filter 130, through the purified water supply line 604. Flows into 210.

In the above description, an embodiment in which the first drain valve 510 is provided in the plurality of intake ports has been described. However, the same embodiment as the third embodiment may be modified by configuring a valve such as the flow path switching valve 550 in one intake port. .

<Sixth Embodiment>

12 is a view showing the configuration of a water treatment apparatus according to a sixth embodiment of the present invention, the sterilization module 300 is installed in the lower portion of the first storage tank 210, the sterilization material is inside the first storage tank 210. It is supposed to flow directly into.

In the first to fifth embodiments, the sterilized water is generated by using the wastewater generated by the reverse osmosis membrane filter 130, and the sterilized water is generated in the first storage tank 210 and the second storage tank 220. In the sixth embodiment, the wastewater generated by the reverse osmosis membrane filter 130 is filled in the first storage tank 210 and then sterilization module 300 is operated to generate sterilization water. There is a difference in .

A wastewater drain line 611 is connected to the wastewater outlet 133 of the reverse osmosis membrane filter 130, and the first storage tank 210 and the second storage tank 220 are connected by a connection line 621. And a wastewater supply line 623 connecting between the wastewater drainage line 611 and the connection line 621, and on the wastewater supply line 623, the wastewater is discharged toward the first storage tank 210. Waste water supply valve 340 for controlling the supply is provided.

In the position adjacent to the second storage tank 220 of the connection line 621, a waste valve 350 is installed to block the inflow of the waste water into the first storage tank 210 and to prevent the inflow into the second storage tank 220. do.

The first storage tank 210, the upper space 210a for storing the filtered water at room temperature state, and the separation plate 213 is installed between the upper space 210a and the lower space for storing cold water (210b) and extends downward from the separation plate 213 to pass through the interior of the water in the upper space (210a) is not mixed with the water of the lower space (210b) to the connection line 621 It includes a connecting passage 214 across the lower space 201b to be supplied to the second storage tank 220 through.

In the present embodiment, the sterilization module 300 is installed on the connection line 621 connected to the lower side of the connection flow path 214 and operates the sterilization module 300 to store water stored in the first storage tank 210. The electrolysis is to produce a sterilization material, the first storage tank 210 to fill the waste water generated by the reverse osmosis membrane filter 130 and then operate the sterilization module 300 to increase the concentration of the sterilization material. It can increase.

Since the sterilization mode according to the sixth embodiment of the present invention is performed in the order of drainage → wastewater inflow → generation of sterilization water → sterilization water drainage → rinsing water inflow → rinsing water drainage → purified water inflow, the following will be described with reference to FIGS. 13 to 17. The sterilization action of the water treatment device according to the sixth embodiment will be described.

13 is a view showing the operation state when draining in the water treatment apparatus according to a sixth embodiment of the present invention, Figure 14 is a view showing a wastewater inflow process in the water treatment apparatus according to a sixth embodiment of the present invention, Figure 15 FIG. 16 is a view illustrating a process for generating sterilizing water in a water treatment apparatus according to a sixth embodiment of the present invention; FIG. 16 is a view illustrating a process for draining sterilizing water in the water treatment apparatus according to the sixth embodiment of the present invention; FIG. 17 is a sixth embodiment of the present invention. Figure showing the rinsing water inflow process in the water treatment apparatus according to the example.

When the sterilization mode is activated, as shown in FIG. 13, the raw water valve 150, the sterilization module 300, and the wastewater supply valve 340 are in an off state, the shutoff valve 350, and the first drain valve 510. And the second drain valve 520 operates the drain pump 530 in an on state to drain all of the water in the first storage tank 210 and the second storage tank 220, and when the drainage is completed, the second drain valve 520 operates. The first drain valve 510, the second drain valve 520, and the drain pump 530 are all in an off state.

In addition, in the present embodiment, the completion time of the drainage may be set to a time to drain for a predetermined time, it may be configured to detect that the drainage is completed by detecting the difference in voltage / current in the drainage pump 530, flow rate It may be configured to install a separate sensor 551, such as a sensor or an infrared sensor to determine the completion point of the drainage.

When the drainage is completed as described above, the wastewater inflow process proceeds, as shown in FIG. 14, the sterilization module 300, the shutoff valve 350, the first drain valve 510, the second drain valve 520, and the drain pump. 530 is an off state, when the raw water valve 150 and the waste water supply valve 340 is On (on), the raw water is introduced and the purified water filtered in the reverse osmosis membrane filter 130 is a post carbon filter ( Some of the wastewater which is introduced into the first storage tank 210 and not filtered by the reverse osmosis membrane filter 130 is discharged to the outside through the wastewater regulator 540 and the wastewater drainage line 611 and the rest of the wastewater. It is introduced into the first storage tank 210 through the waste water supply line 623 and the connection line 621.

When the inflow of wastewater to the first storage tank 210 is completed, the sterilization water generation process is performed. As shown in FIG. 15, all the valves 150, 340, 350, 510, and 520 are turned off to open the inside of the first storage tank 210. After forming into a closed space and operating the sterilization module 300, the sterilizing material is introduced into the upper space 210a through the connection passage 214, and then the sterilizing material is also added to the lower space 210b connected to the upper space 210a. The first storage tank 210 is diffused and filled with sterilizing water, and the sterilizing action is waited for a predetermined time while the sterilizing water is filled.

When the sterilization of the inside of the first storage tank 210 is completed as described above, the sterilizing water discharge process is performed. As shown in FIG. 16, the shutoff valve 350 is turned on before discharging the sterilizing water to the outside. The sterilizing water in the first storage tank 210 is filled in the second storage tank 220 to sterilize the inside of the connection line 621 and the second storage tank 220. In this case, only the sterilizing water in the upper space 210a of the first storage tank 210 is filled in the second storage tank 220, and the sterilizing water in the lower space 210b does not flow into the second storage tank 220 and remains as it is. Will be.

Meanwhile, the sterilization module 300 is turned off immediately before waiting for a predetermined time after the sterilization water is filled in the first storage tank 210 or just before draining the sterilization water in the first storage tank 210. The first storage tank 210 may be modified to another time point if it is determined that the inside of the first storage tank 210 is sufficiently sterilized.

When the sterilizing water in the first storage tank 210 is filled in the second storage tank 220, the first drain valve 510 and the second drain after waiting for a predetermined time to effect sterilization in the second storage tank 220. By turning on the drain valve 520 and operating the drain pump 530, the sterilizing water in the lower space 210b of the first storage tank 210 and the sterilizing water in the second storage tank 220 are moved to the outside. Drain .

When the drainage of the sterilizing water is completed, the rinsing water inflow process is performed. As shown in FIG. 17, the raw water valve 150, the wastewater supply valve 340, and the shutoff valve 350 are turned on and the first drain valve is turned on. When the 510 and the second drain valve 520 are turned off, the reverse osmosis membrane as well as the purified water filtered through the filter unit 100 are stored in the first storage tank 210 and the second storage tank 220. Wastewater generated by the filter 130 is also filled.

As such, when the rinsing water inflow process is completed, the rinsing water draining process is performed. In the rinsing water draining process, the opening state of each valve is the same as that of the purified water draining process, as shown in FIG. 13. By operating the drain pump 530 while the 510 and the second drain valve 520 are turned on, the rinsing water in the first storage tank 210 and the second storage tank 220 is drained to the outside. do.

When the rinsing water drainage process is completed, the purified water inflow process is performed. In the purified water inflow process, the open state of each valve is the same as that in FIG. 17 except that the wastewater supply valve 340 is off. When the purified water is filled up to the full water level in the 210 and the second storage tank 220, the sterilization mode ends.

In the above, the sterilization water is generated after the inflow of the waste water, but in order to shorten the sterilization time, the sterilization module 300 may be operated at the same time as the inflow of the waste water.

Seventh Embodiment

18 is a view showing the configuration of the water treatment apparatus according to the seventh embodiment of the present invention, the sterilization module 300 is installed in the lower portion of the first storage tank 210 and the sterilization water generated in the sterilization module 300 1 is configured to circulate the storage tank 210 inside.

Compared to the sixth embodiment, the present embodiment includes a circulation line 624 interconnecting the connection line 621 and the first storage tank 210 and sterilizing water in the first storage tank 210. A circulation pump 360 for circulating through the connection line 621 and the circulation line 624 is further provided, and the circulation line 624 is branched from the connection line 621 to the first storage tank 210. It is connected to communicate with the lower space (210b) of.

The sterilization material generated by the sterilization module 300 is introduced into the connection passage 214 inside the first storage tank 210 and first spreads to the upper space 210a. The circulation pump 360 is operated to operate the circulation line. By circulating water in the first storage tank 210 through 624, the concentration of the sterilizing material in the upper space 210a and the lower space 210b may be uniform.

On the other hand, a shutoff valve 370 is installed on the circulation line 624. When the purified water filtered through the filter part 100 is supplied to the first storage tank 210, the shutoff valve 370 is turned off. By doing so, the cold water in the lower space 210b may be prevented from entering the second storage tank 220 through the circulation line 624, thereby preventing the hot water efficiency from dropping.

<Experimental Results>

19 is a configuration diagram for measuring the residual chlorine concentration according to the installation position of the sterilization module in the water treatment apparatus of the present invention, with reference to FIG.

In this experiment, the sterilization module 300 is installed at the front end of the inlet 131 of the reverse osmosis membrane filter 130 or the sterilization module 300 is installed at the rear end of the wastewater outlet 133 of the reverse osmosis membrane filter 130. In the state configured to generate sterilization water using wastewater that did not pass through the membrane filter 130, the residual chlorine concentration of the sterilization water generated in the sterilization module 300 was measured to see whether it is suitable to function as sterilization water. For sake.

division tap water Sterilization Module Location Reverse Osmosis Membrane Filter Shear Reverse Osmosis Membrane Filter Rear Residual Chlorine (ppm) 0.15 0.87 1.06 0.13 0.92 1.01 0.17 0.84 1.12 Average 0.15 0.88 1.03

First, the first experimental result, as shown in Figure 19 (a), the sterilization module 300 is installed in front of the inlet 131 of the reverse osmosis membrane filter 130, the residual chlorine in the waste water containing the sterilizing material When the concentration was measured, the average was 0.88 ppm.

In addition, the second experimental result is that, as shown in Figure 19 (b), the sterilization module 300 is installed at the rear end of the wastewater outlet 133 of the reverse osmosis membrane filter 130, the wastewater passing through the sterilization module 300 The residual chlorine concentration was found to be 1.03 ppm on average.

Normally, the effective chlorine concentration administered by water and sewage treatment plant is between 0.2 ~ 0.8ppm, and the effective chlorine concentration of tap water flowing into and out of home is about 0.2 ~ 0.4ppm. can not do it.

Therefore, in the case of the present invention, as shown in the above experimental results, it is possible to generate sterilized water having an average chlorine concentration of 0.88 ppm or 1.03 ppm, which is sufficient to function as sterilized water.

The result value may vary according to the chlorine ion concentration of the tap water and the structure of the sterilization module and the combination of the electrodes, the concentration may vary depending on the current value applied to the electrode, the structure of the sterilization module and the combination of the electrodes and the current value By applying a sterilization module having a higher efficiency through regulation, etc., the concentration of the sterilizing substance can be increased.

According to the present invention as described above, by using the wastewater generated in the reverse osmosis membrane filter to generate the sterilized water can be minimized waste of water, and using a dissolved ionic material contained in the waste water of a high concentration of sterilizing material Sterilization efficiency can be improved, and if the sterilization module is installed in front of the reverse osmosis membrane filter, the sterilization material generated from the sterilization module sterilizes the bacteria grown on the filter membrane of the reverse osmosis membrane filter. Can be supplied to In addition, the sterilized water can be sterilized to the inside of the intake line in the process of draining the sterilized water, thereby minimizing the area of the dead zone which is not sterilized in the water treatment apparatus.

As described above, the present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the scope of the present invention as defined in the appended claims. And such modifications are within the scope of the present invention.

100 filter unit 110 pretreatment precipitation filter
120: pre-carbon filter 130: reverse osmosis membrane filter
131: inlet 132: water purification outlet
133 wastewater outlet 140 post carbon filter
150: raw water valve 200: storage unit
210: first storage tank 210a: upper space
210b: Lower space 211: Water level sensor
212: ball tower 213: separation plate
214: connection flow path 220: second storage tank
300: sterilization module 310,330: sterilization water supply valve
320: water shutoff valve 340: wastewater supply valve
350: shut-off valve 360: circulation pump
400: water intake 410: first intake valve
420: second intake valve 500: drain
510: first drain valve 520: second drain valve
530: drainage pump 540: wastewater regulator
550: flow path switching valve 601,602,603: raw water supply line
604: water supply line 611: wastewater drainage line
612: sterilization water supply line 621: connection line
623: wastewater supply line 624: circulation line
631: first intake line 632: second intake line
633: 3rd water intake line

Claims (12)

A filter unit including a reverse osmosis membrane filter to filter raw water;
A storage unit for storing the water filtered by the filter unit at different temperatures and including a first storage tank and a second storage tank interconnected by connection lines;
A wastewater supply line configured to supply the wastewater generated by the reverse osmosis membrane filter to the first storage tank;
A sterilization module installed on a flow path connected to the waste water supply line to supply sterilization water to the storage unit;
Water treatment device comprising a The method of claim 1,
The wastewater supply line is branched from the wastewater drainage line for discharging the wastewater generated by the reverse osmosis membrane filter to the outside is connected to the connection line The method of claim 1,
The first storage tank may include an upper space for storing the filtered water at a normal temperature state, a lower space for storing cold water, the lower space being provided with a separation plate between the upper space and the lower space, And a connecting flow channel which crosses the lower space so that the water in the lower space is not mixed with the water in the lower space and is supplied to the second storage tank through the connection line through the inside thereof;
The sterilization module is characterized in that the water treatment device is installed on the connection line connected to the lower side of the connection flow path The method of claim 1,
And a circulation line branched from the connection line for interconnecting the first storage tanks and circulating the sterilized water in the first storage tank through the connection line and the circulation line to the inside of the first storage tank Characterized by comprising a circulation pump 5. The method of claim 4,
On the circulation line, when the purified water filtered through the filter unit to the first storage tank is provided with a shut-off valve for blocking the water in the lower space of the first storage tank flows into the second storage tank. Water treatment equipment The method of claim 1,
A wastewater supply valve is installed on the wastewater supply line to control whether wastewater is supplied to the first storage tank, and on the connection line, the wastewater is supplied only to the first storage tank, and the wastewater is introduced into the second storage tank. Water treatment device characterized in that the shut-off valve is provided to block the The method of claim 1,
The water treatment device, characterized in that the sterilization module is operated in a state in which water is introduced into the first storage tank or water is prevented from flowing out of the first storage tank. The method of claim 1,
Wherein the first storage tank and the second storage tank are connected to a first drain line and a second drain line for draining the sterilized water filled in the first storage tank and the second storage tank, respectively. 9. The method of claim 8,
The first wastewater line is branched on the intake line connecting between the first storage tank and the intake valve is connected to the wastewater drainage line, characterized in that 9. The method of claim 8,
Water stored in the first storage tank and the second storage tank is discharged through one intake port through a plurality of intake lines; And a flow path switching valve for switching the discharge direction of the water supplied from the first and second storage tanks is provided at a point where the first drain line and the water intake line cross each other, 9. The method of claim 8,
Wherein the first drain line and the second drain line are each provided with a drain valve for controlling drainage of sterilized water, 9. The method of claim 8,
Characterized in that a drain pump is provided to smooth drainage of sterilized water through the first drain line and the second drain line

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