KR20190035293A - A method keeping salinity of regeneration water - Google Patents

Abstract

The present invention is to provide a salinity maintaining method for regenerated water inside a regenerating container, including a regeneration agent, of a water softener, which comprises: a step (a, S100) in which a flow rate temperature sensor (520) measures temperature and water pressure of cold water to be regenerated, which is supplied to a regenerating container (700); a step (b, S200) in which a control unit (1100) inputs the temperature and water pressure of the cold water to be regenerated, which are measured by the flow rate temperature sensor (520); a step (c, S300) in which the control unit (1100) loads dissolution time of a regeneration agent according to the temperature and water pressure of the cold water to be regenerated, from a database (DB) that stores the dissolution time information of the regeneration agent according to the temperature and water pressure of the cold water to be regenerated, thereby calculating the dissolution time of the regeneration agent accordingly; and a step (d, S400) which dissolves the regeneration agent inside the regenerating container (700) with the cold water to be regenerated for the dissolution time calculated in the step (c). Therefore, the salinity maintaining method for regenerated water can consistently maintain the salinity of regenerated water discharged from a regenerating container (700) by regulating dissolution time of a regeneration agent.

Description

[0001] The present invention relates to a salinity regeneration method,

The present invention relates to a method for controlling the dissolution time of a regenerant to maintain the salinity of the regenerated water.

When tap water (hereinafter referred to as "hard water") contains a large amount of chlorine ions during the purification process, and when the raw water of the tap water itself is contaminated by passing through old pipes, iron, zinc, lead and mercury A variety of heavy metal ions are included.

These heavy metal ions can be combined with fatty acids of soap, in particular, to produce metallic foreign substances, which can contact the skin and cause allergies or skin aging.

In order to prevent this, the hard water is passed through strongly acidic cations such as sodium ions (Na +) and calcium ions (Ca2 +) and magnesium ions (Mg2 +), which are hardness components, are exchanged with sodium ions Ion (Ca2 +) and magnesium ion (Mg2 +) can be generated. Thus, many water softeners are used to convert hard water into soft water.

An ion resin tank in which water containing sodium ions (Na +) is stored for exchanging calcium ions (Ca2 +) and magnesium ions (Mg2 +), which are hardness components, with sodium ions (Na +), The resin tank is composed of a hot water tank and a cold water tank.

At this time, when the user continues to use the soft water stored in the hot water tank and the cold water tank, sodium ions (Na +) in the hot water tank and the cold water tank are continuously consumed, It is necessary to replenish ions (Na +).

To this end, the water softener is provided with a regenerator, and after regenerated water containing sodium ions (Na +) is generated in the regenerator, the regenerated water is supplied to the hot water tank and the cold water tank to supplement sodium ions (Na +) .

Specifically, a basket is provided in the regenerator, the regenerant is contained in the basket, and the raw water introduced into the regenerator melts the regenerant to generate regenerated water.

KR 2002-0014922A discloses a method for regenerating an ion exchange resin for a water softener, comprising the steps of: (a) injecting an ion exchange resin regeneration liquid containing 20-40% NaCl into a column having an ion exchange resin for a water softener; (C) draining the regeneration liquid from the column; and (d) rinsing the column to discharge the exchanged hardness component to the outside. And a method for regenerating an ion exchange resin for a water softener.

In this way, conventionally, the time for supplying raw water into the regenerator is defined as the start time, and the time for supplying the regenerated water to the hot water tank or the cold water tank is regarded as the end time.

At this time, in the process of supplying the raw water into the regenerator, the raw water inevitably melts the regenerant.

However, the pressure of the raw water flowing into the regeneration vessel is different for each water outlet of the place where the water softener is installed. In a place where the raw water pressure is strong, a large amount of regenerant is melted in the process of the raw water flowing into the regeneration vessel. In a place where the raw water pressure is weak, a relatively small amount of regenerant is melted.

That is, although the pressure of the raw water differs for each assumption, the replenishment water is generated for the same period of time.

In addition, since the temperature of the raw water to be introduced differs depending on the season, even if the raw water is stagnated in the regenerator for the same time to melt the regenerant, the amount of the regenerant to be melted varies depending on the temperature of the raw water to be introduced, There arises a problem that the salinity of the saline solution varies.

As described above, if the salinity of the regenerated water varies depending on the pressure and the temperature of the raw water flowing into the regenerator, ultimately, the regenerator can not provide the user with a constant hardness.

Accordingly, there is a great need for a technique capable of maintaining the salinity of the regenerated water at a constant level, despite the fact that the temperature and the pressure of the raw water flowing into the regeneration vessel are different.

(Patent Document 1) KR 2002-0014922A

(Patent Document 2) KR 2004-0091290A

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems.

Specifically, it is intended to provide a method for controlling the salinity of the regenerated water, which maintains the salinity of the regenerated water at a constant level, even if the pressure and temperature of the raw water flowing into the regenerator vary.

Particularly, it is desired to produce the regenerated water of uniform salinity by forming the regenerated water at different times according to the pressure and temperature of the raw water flowing into the regenerator.

According to an aspect of the present invention, there is provided a method for maintaining salinity of a reclaimed water in a regenerator of a water softener, the regenerator including a regenerant, wherein (a) (S100) the temperature and the water pressure of the regeneration cold water supplied to the regeneration cold water supply unit (700); (b) a step S200 of inputting the temperature and the water pressure of the regeneration cold water measured by the flow rate temperature sensor 520 to the control unit 1100; (c) The control unit 1100 reads the temperature of the regeneration cold water and the dissolution time of the regenerant according to the water pressure from the database (DB) storing the regeneration agent dissolution time information corresponding to the regeneration cold water temperature and water pressure (S300) in which the dissolution time of the regenerant is calculated; And (d) dissolving the regenerant in the regenerator (700) with the cold water for regeneration during the dissolving time of the regenerant calculated in the step (c) (S400); Wherein the regeneration time of the regenerant is controlled to maintain the salinity of the regeneration water discharged from the regeneration reactor 700 at a constant level.

In the step (d), the control unit 1100 may control the regeneration of the regeneration agent to the cold water tank 200 or the hot water tank 400 in which the ion exchange resin is embedded, Controlling the valve so that the replenishing water in the cylinder 700 is supplied (S420); .

Also, the regenerant dissolution time in the step (e) may be such that the regenerating cold water dissolves the regenerant during the regenerant dissolution time on the basis of the time when the regeneration cold water is supplied to the regenerator 700 .

In the step (a), it is preferable that the water pressure of the cold water for regeneration is calculated by the flow rate of the cold water for regeneration.

Further, it is preferable that the salinity of the regeneration water discharged from the regenerator 700 is 9%.

In the step (b), furthermore, the regeneration time is further inputted, and in the step (c), the regeneration agent dissolution time information according to the temperature, water pressure and regeneration time of the regeneration cold water is stored It is preferable that the dissolving time of the regenerant is calculated by loading the temperature of the regeneration cold water, the water pressure, and the regeneration time from the database (DB) having the regeneration agent.

In the step (a), the regeneration cold water supplied to the regeneration tank 700 is regulated by the control unit 1100, and the amount of regeneration cold water, which is confirmed by the flow temperature sensor 520, When the predetermined amount is reached, the controller 1100 controls the valve to shut off the regeneration cold water supplied to the regenerator 700.

Further, the water softener includes a regeneration flow passage 500 communicating with the cold water receiving portion 100; And a connector for supplying the regeneration cold water from the regeneration passage 500 to the regenerator 700 and supplying the regenerated water to the cold water tank 200 or the hot water tank 400 600).

The water softener may further include: the cold water receiving unit 100; The cold water tank 200 for supplying cold water to the regeneration flow path 500 as cold water for regeneration while receiving cold water from the cold water receiving part 100 and exiting the water by ion exchange; A hot water receiving unit 300; The hot water tank 400 receives hot water from the hot water receiving unit 300 and ion-exchanges the hot water. The regenerator (700); A cold water drain (800) having one end connected to the cold water tank (200) and the other end connected to the drain (820); A hot water drain (900) having one end connected to the hot water tank (400) and the other end connected to the drain (820); A cold water valve 190 located in the cold water inlet 100; A hot water valve 390 located in the hot water receiving part 300; A regeneration supply valve 590 located in the regeneration passage 500; A cold water rinse valve 890 located in the cold water drain 800; And a hot water rinse valve (990) located in the hot water drain (900), wherein the cold water valve (190) and the regeneration supply valve (590) are opened, and the cold water rinse valve It is preferable that the regeneration cold water is supplied to the regenerator 700 by closing the regenerator 890.

In the step (d), the regeneration supply valve 590, which was opened in the step (a), is closed to block the regeneration cold water supplied to the regeneration reactor 700, It is preferable to dissolve the regenerant through the regeneration cold water carried in the regeneration cold water.

In the step (d-1), it is preferable that the cold water valve 190 is closed and the cold water rinse valve 890 is opened so that the purified water is supplied to the cold water tank 200.

In the step (d-1), it is preferable that the hot water valve 390 is closed and the hot water rinse valve 990 is opened so that the regenerated water is supplied to the hot water tank 400.

The present invention can maintain the salinity of the regenerated water supplied to the cold water tank or the hot water tank at a constant level by regulating the dissolving time for the regenerating cold water supplied to the regenerator to dissolve the regenerant.

Further, the regenerant dissolution time is based on the time when the regeneration cold water is supplied to the regenerator, so that it can be considered that the regenerant is dissolved in the process of filling the regenerator with the regeneration cold water to affect the salinity.

In addition, by determining the dissolution time in consideration of a change in the temperature of the cold water for regeneration according to the season, ultimately, it is possible to provide a user with a constant hardness.

1 is a perspective view showing the appearance of a water softener according to the present invention.
2 and 3 are perspective views of a water softener according to the present invention, in which the upper cover and the lower cover are removed for the sake of explanation and the illustration of the frame and some connecting parts is omitted. As can be seen from the coordinate system, FIG. 3 is a perspective view seen from the upper rear side. FIG.
4 is a perspective view showing a connector of a water softener according to the present invention.
5A is a view schematically showing a flow path of a water softener according to the present invention.
FIG. 5B is a view schematically showing a flow path for supplying cold water for regeneration (steps C11 and C21 below) in the water softener according to the present invention.
FIG. 5C is a view schematically showing a flow path (step C13) for supplying regeneration water to the cold water tank in the water softener according to the present invention. FIG.
FIG. 5D is a view schematically showing a flow path for supplying the regenerated water to the hot water tank (step C24 described below) in the water softener according to the present invention. FIG.
6 is a view for explaining the operation mode of the water softener according to the present invention and the operation of the corresponding valve.
FIG. 7 is a block diagram for explaining a method of maintaining salinity of saline according to the present invention.
FIG. 8 is a flow chart for explaining the method of maintaining the salt water salinity according to the present invention.

Hereinafter, "cold water" and "hot water" refer to fluids individually supplied from a cold water outlet and a hot water outlet to a water softener.

The term "regenerated water" means a fluid for supplying ions to the ion exchange resin by melting a regeneration block, which may be, for example, salt. Is referred to as "cold water regenerated water" when supplied to the cold water tank, and "hot water regenerated water" when supplied to the hot water tank.

"Cold water for regeneration" means cold water supplied to generate regeneration water.

1. Description of water softener

Hereinafter, a water softener according to the present invention will be described with reference to Figs. 1 to 5D.

1 shows an upper cover 1010 and a lower cover 1020 in the appearance of a water softener according to the present invention. For clarity, the top cover 1010 is shown as transparent.

A regenerator 700 is located inside the upper cover 1010 and a filter cover 221 of the cold water tank 200 and a filter cover 421 of the hot water tank 400 are located at the lower end of the regenerator 700. Replace the filter, or remove the top cover 1010 to fill the regenerator 700 with a regeneration block (not shown).

A control panel 1011 is located inside the upper cover 1010. The control panel 1011 is provided with a notification window for displaying the number of times of reproduction and an input section for inputting the current time setting, reproduction setting, Kare mode, and manual reproduction.

The lower cover 1020 protects the inner flow path.

A performance indicator 1021, a playback indicator 1022, and a battery indicator 1023 may be located on the lower cover 1020.

FIGS. 2 to 3 show a water softener in which the upper cover 1010 and the lower cover 1020 are removed. The illustration of the frame and the connecting parts for fixing the respective parts to the frame is omitted for the sake of explanation.

Fig. 4 shows the connector 600, and Figs. 5A to 5D schematically show the flow path. In FIGS. 2 to 3, the illustration of the tube to which the components are connected is omitted, which will be described below with reference to FIGS. 5A to 5D.

Hereinafter, a water softener according to the present invention will be described with reference to FIGS. 2 to 5D.

1.1 The cold water supply unit (100)

The water softener according to the present invention includes a cold water receiving portion 100, a cold water tank 200, a hot water receiving portion 300, a hot water tank 400, a regeneration flow path 500, a connector 600, a regenerator 700, A cold water drain 800 and a hot water drain 900.

The cold water receiving unit 100 is located at the lower end of the water softener and is connected to a cold water outlet (not shown) to supply cold water as raw water to the water softener. A cold water inlet 110, a pressure reducing valve 120, a flow rate sensor 130, and a cold water valve 190.

The cold water inlet 110 is connected to a cold water outlet to receive cold water. The supplied cold water passes through the pressure reducing valve 120, is depressurized, and the cold water flow rate supplied by the flow rate sensor 130 is confirmed.

The cold water valve 190 is provided between the cold water inlet 110 and the cold water inlet passage 210 to control the inflow of cold water. The cold water valve 190 is controlled according to the operation mode, and the details will be described later.

1.2 Cold water tank (200)

The cold water tank 200 serves to soften the cold water supplied from the cold water receiving unit 100 and supply it to the regeneration tank 700 as the cold water for regeneration. A cold water inlet channel 210, a filter unit 220, a cold water ion exchange resin 230, and a cold water outlet 240.

2 and 3, the cold water supply channel 210 is connected to the cold water supply unit 110 and is installed in the center of the cold water tank 200 and is filled in the cold water ion exchange resin 230 . The cold water introduced through the cold water intake flow path 210 is raised.

The filter unit 220 is located at the end of the cold water supply channel 210 and the cold water supplied through the cold water supply channel 210 is filtered by the filter unit 220. The user can open the filter cover 221 of the cold water tank 200 to replace the filter.

The cold water that has passed through the filter unit 220 flows radially outward and then descends or is supplied to the cold water for regeneration through the cold water inlet for recycling (510) as a tube (see FIGS. 5A to 5D). A part of the refrigerant flows to the cold water replenishing water outlet channel 640 including other tubes, but does not flow to the connector 600 by the check valve 645, but only the oil pressure in the oil passage is maintained.

The cold water that has flowed radially outward through the filter unit 220 and then flows through the cold water ion exchange resin 230 is softened by the ion exchange function. The softened cold water is delivered to the user through the cold water outlet (240).

1.3 The hot water intake part (300)

The hot water receiving unit 300 is located at the lower end of the water softener and is connected to a hot water outlet (not shown) to supply hot water, which is raw water, to the water softener. A hot water inlet 310, a pressure reducing valve 320, a flow rate sensor 330, and a hot water valve 390.

Similarly, the hot water inlet 310 is connected to the hot water outlet to receive the hot water, and the supplied hot water is depressurized through the pressure reducing valve 320 and the hot water flow rate supplied by the flow rate sensor 330 is confirmed.

The hot water valve 390 is provided between the hot water inlet port 310 and the hot water inlet flow path 410 and controls whether hot water is introduced.

1.4 Hot water tank (400)

The hot water tank 400 serves to soften the hot water supplied from the hot water receiving unit 300 and to take out the hot water. Unlike the cold water tank 200, the hot water is not supplied to the regenerator 700. A hot water inlet flow path 410, a filter portion 420, a hot water ion exchange resin portion 430, and a hot water outlet 440.

The hot water inlet channel 410 is connected to the hot water inlet 310 and is provided in the center of the hot water tank 400 as shown in FIGS. 2 and 3, and is filled in the hot water ion exchange resin 430 . The hot water flowing through the hot water inlet channel 410 is raised.

The filter unit 420 is located at the end of the hot water inlet flow path 410 and the hot water supplied through the hot water inlet flow path 410 is filtered by the filter unit 420. The user can open the filter cover 421 of the hot water tank 400 to replace the filter.

The hot water that has passed through the filter unit 420 flows radially outward and then descends but is not supplied to the regeneration flow path 500 unlike the cold water tank 200. A portion thereof flows to the hot water regenerating water outlet path 660 including the tube and does not flow to the connector 600 by the check valve 665 but only the hydraulic pressure in the flow path is maintained.

The hot water flowing through the filter unit 420 and radially outwardly flowing through the hot water ion exchange resin 430 is softened by the ion exchange function. The softened hot water is delivered to the user through the hot water outlet 440.

1.5 < tb >

The regeneration flow path 500 serves to supply the cold water supplied through the cold water receiving section 100 and the cold water tank 200 to the regenerator 700 through the connector 600 as cold water for regeneration to generate regenerated water. A regeneration cold water supply path 510, a flow temperature sensor 520, a connector intake path 530, and a regeneration supply valve 590.

One end of the regeneration cold water supply path 510 is connected to the cold water tank 200 by a tube and the other end is connected to the connector intake path 530 by another tube.

A regeneration supply valve 590 and a flow rate temperature sensor 520 are provided in the regeneration cold water supply passage 510. [ The regeneration supply valve 590 is controlled in accordance with the operation mode, details of which will be described later. The flow rate and temperature of the regeneration cold water sensed by the flow rate temperature sensor 520 can be used for determining the number of regeneration times and determining the regeneration time.

1.6 connector (600)

The connector 600 supplies the regeneration cold water supplied from the regeneration flow path 500 to the regenerator 700 and transfers the regenerated water generated in the regenerator 700 to the cold water tank 200 and the hot water tank 400 It plays a role. And is connected to the water inlet line 610, the cold water replenishing water outlet channel 640 and the check valve 645 provided therein, the hot water replenishing water channel 660 and the check valve 665 provided therein, And includes a regenerator flow passage 680.

The inlet channel 610 is connected to the connector inlet channel 530, and the regeneration cold water is supplied to the regenerator 700 through the inlet channel 610.

The regenerator 700 is connected to one end of the cold water regenerating water outlet channel 640 and the other end is connected to the cold water tank 200. Cold water is normally filled in the flow path from the check valve 645 to the cold water tank 200 in the cold water replenishment water outlet passage 640 to maintain a constant hydraulic pressure. As described above, the cold water is not transmitted to the regenerator 700 due to the check valve 645. [ At the time of regeneration, cold water regenerated water is supplied to the cold water tank 200 through the cold water regeneration water outlet channel 640 in the regenerator 700.

Likewise, the regenerator 700 is connected to one end of the hot water regenerating water channel 660 and the other end is connected to the hot water tank 400. The hot water is filled in the flow path from the check valve 665 to the hot water tank 400 in the hot water regeneration water outlet passage 660 so that the constant hydraulic pressure is maintained and the hot water is transmitted to the regenerator 700 by the check valve 665 It does not. At the time of regeneration, hot water regenerated water is supplied to the hot water tank 400 through the hot water regenerating water outlet path 660 in the regenerator 700.

The cold water passes through the filter unit 220 and is filled up to the check valve 645 of the cold water replenishment water channel 640. The hot water passes through the filter unit 420 and flows into the hot water The check valve 665 of the replenishing water outlet channel 660 is filled. In the water softener according to the present invention, the cold water tank 200 and the hot water tank 400 can communicate with each other through the cold water regeneration water channel 640 and the hot water regeneration water channel 660. The check valves 645 and 665 So that the mixing can be prevented at all times. The regeneration water generated in one regenerator 700 can be supplied to both the cold water tank 200 and the hot water tank 400 due to the check valves 645 and 665 as will be described later.

One end of the regenerating channel 680 is connected to the regenerator 700 and the other end is connected to all three channels, that is, the inlet channel 610, the cold water regeneration water outlet channel 640, and the hot water regeneration water outlet channel 660 . When the cold water for regeneration is supplied, the cold water for regeneration passes through the inlet channel 610 and the regenerator channel 680, and the regeneration cold water flows upward in the regenerator channel 680. On the other hand, the cold water regeneration water passes through the regeneration channel 680 and the cold water regeneration water channel 640, and the hot water regeneration water passes through the regeneration channel 680 and the hot water regeneration water channel 660, ). ≪ / RTI >

1.7 Regenerator (700)

The regenerator 700 receives regeneration cold water from the connector 600 and generates regenerated water.

A regeneration block (not shown) may be filled in the regenerator 700. When the cold water for regeneration is supplied to the regenerator 700 through the cold water inlet 110, the cold water inlet passage 210, the filter portion 220, the regeneration cold water inlet passage 510, and the inlet passage 610, (Not shown) melts to generate a reproduction number.

Here, the cold water regeneration water and the hot water regeneration water are divided according to whether they are supplied to the cold water tank 200 or the hot water tank 400 as the same regenerated water generated in the regenerator 700. That is, a part of the regenerated water generated in the regenerator 700 is supplied to the cold water tank 200 through the cold water regeneration water channel 640 of the connector 600. The regenerated water supplied at this time is the cold water regenerated water, And is supplied to the hot water tank 400 through the hot water regeneration water outlet channel 660 of the hot water regeneration unit 600. The regenerated water supplied at this time is hot water regenerated water. Generally, cold water regeneration water is first supplied to the cold water tank 200, and hot water regeneration water is supplied to the hot water tank 400.

When the cold water is introduced into the cold water tank 200, it is supplied to the cold water ion exchange resin 230 to regenerate the ions of the cold water ion exchange resin 230.

Similarly, when the hot water regeneration water flows into the hot water tank 400, it is supplied to the hot water ion exchange resin 430 to regenerate the ions of the hot water ion exchange resin 430.

The lower end of the regenerator 700 may be connected to the drain 820 by a tube so that the regenerated water or the rinsed water overflowed in the regenerator 700 is discharged through a drain 820 have.

1.8 Cold water drain (800)

The cold water drain 800 functions to drain the rinsed water to the cold water tank 200. A cold water rinse outflow passage 810, a drain 820, and a cold water rinse valve 890.

One end of the cold water rinse outflow path 810 is connected to the cold water tank 200 by a tube and the other end is connected to the drain 820 by another tube and a cold water rinse valve 890 is provided. The drain 820 communicates with the outside of the water softener.

1.9 hot water drain (900)

The hot water drain 900 serves to drain the rinsed water through the drain 820 to the hot water tank 400. A hot water rinse water outlet path 910 and a hot water rinse valve 990.

Similarly, one end of the hot water rinse water path 910 is connected to the hot water tank 400 by a tube, and the other end is connected to the drain 820 by another tube, and a hot water rinse valve 990 is provided.

2. Explanation of operation mode of water softener

The operation mode of the water softener according to the present invention will be described with reference to FIG.

The operation mode of the water softener according to the present invention can be divided into (A) a raw water mode, (B) a training mode, (C) a regeneration mode, and (D) a regeneration mode.

Each mode can be implemented through the control of five valves: a cold water valve 190, a hot water valve 390, a regeneration supply valve 590, a cold water rinse valve 890, and a hot water rinse valve 990. Conventional water softener generally uses one multiway valve including a ceramic disk. However, due to the characteristics of the water softener operating in a humid environment, the water softener is often a malfunction, leading to leakage or failure. The operation mode is realized by dividing the valves.

It is preferred that the cold water valve 190, the hot water valve 390, the regeneration supply valve 590, the cold water rinse valve 890 and the hot water rinse valve 990 are both latch valves but other types of electronically controllable Of course, the valve is also possible.

(A) Raw mode is an operation mode in the case where the user uses raw water rather than years, and a detailed description thereof will be omitted.

2.1 Training mode

(B) The training mode is the case where the user uses the soft water, and the cold water valve 190 and the hot water valve 390 are opened and the regeneration supply valve 590, the cold water rinse valve 890, the hot water rinse valve 990, Lt; / RTI >

The cold water valve 190 is opened and the regeneration supply valve 590 is closed so that the cold water supplied through the cold water inlet 110 does not flow into the regeneration passage 500 after passing through the filter unit 220, Exchanged resin 230 and is softened.

Since the cold water rinse valve 890 is closed, the softened cold water is not discharged to the drain 820 but flows out through the cold water outlet 240 as much as the user desires.

The same is true for hot water.

2.2 Playback mode

(C) In the regeneration mode, when ions of the hot water ion exchange resin 430 in the cold water ion exchange resin 230 and the hot water ion exchange resin 430 in the cold water tank 200 are decreased and it is difficult to generate soft water, This is a mode for regenerating the resin. After the regeneration cold water is supplied to the regenerator 700 to generate regeneration water, the regeneration cold water is supplied to the cold water tank 200 and the hot water tank 400 as cold water regeneration water and hot water regeneration water, respectively.

(C) The starting point of the regeneration mode may be set based on the total flow rate of the years used by the user, and / or may be set based on the time from when the last regeneration mode is performed.

For example, if the user uses cold water or hot water that has exceeded a reference flow rate of a total of 600 liters, (C) the regeneration mode can be performed. The amount of the used soft water can be confirmed through the flow sensor 130 on the cold water side and the flow sensor 330 on the hot water side. It is preferable that both the cold water tank 200 and the hot water tank 400 are regenerated if either the cold water or the hot water exceeds the reference flow rate. (C) that the user is unable to use the water softener for about one hour, so that the ion exchange resin on the cold water side and the hot water side is integratedly managed.

At the same time, when eight days have elapsed from the time when the last regeneration mode is performed, (C) the regeneration mode can be performed even if the flow rate used by the user does not exceed the reference flow rate. This is to prepare for the case where the flowmeter is defective or when the function of the ion exchange resin is naturally decreased with time.

(C) the regeneration mode is divided into (C1) a cold water tank regeneration mode and (C2) a hot water tank regeneration mode.

(C1) The cold water tank regeneration mode will be described first. (C11) regeneration cold water supplying step, (C12) dissolving step, (C13) regeneration step, and (C14) rinsing step.

(C11) The regeneration cold water supply step is generally started by changing in the normal mode (B) training mode.

The regeneration supply valve 590, the cold water rinse valve 890 and the hot water rinse valve 990 are closed in the (B) soft water mode, in which the cold water valve 190 and the hot water valve 390 are opened, (590).

The cold water supplied through the cold water inlet 110 flows through the filter unit 220 and flows toward the regeneration cold water intake path 510 due to the opening of the regeneration supply valve 590, , An intake channel 610, and a regenerator channel 680, and is supplied to the regenerator 700. [

The amount of regeneration cold water supplied to the regenerator 700 is confirmed by the flow rate temperature sensor 520. [

When the amount of regeneration cold water detected by the flow rate temperature sensor 520 reaches a predetermined amount (that is, the capacity of the regenerator 700) (C12), the process proceeds to the dissolving step.

Lt; RTI ID = 0.0 > 590 < / RTI > The regeneration supply valve 590 and the cold water rinse valve 890 are both closed and the pressure is maintained so that the regenerated water generated in the regenerator 700 does not flow into the cold water tank 200 but has a dissolving time.

Since the hot water rinse valve 990 is also closed, it does not flow into the hot water tank 400. The dissolution time may be determined differently depending on the temperature, the flow rate, and the like of the cold water for regeneration.

2.2-1 How to maintain salinity of reclaimed water

The method for maintaining the salt water salinity according to the present invention relates to the dissolution step (C12), and regulates the dissolution time of the regenerant so as to maintain the salinity of the regenerated water generated in the regenerator 700 constant.

FIG. 7 is a block diagram schematically showing a method for maintaining a salt water salinity according to the present invention.

7, the cold water for regeneration is supplied to the regenerator 700 by the operation of the valves described above, and the regeneration cold water is supplied to the regenerator 700 through the flow rate temperature sensor 520 .

At this time, the temperature and the flow rate of the regeneration cold water to be supplied are checked by the flow rate temperature sensor 520, the flow rate per hour is calculated by the water pressure, and the information about the temperature and the water pressure of the regeneration cold water, .

Then, the temperature of the cold water for regeneration and the dissolving time of the regenerant according to the water pressure and the temperature of the cold water for regeneration inputted from the database (DB) storing the regeneration agent dissolution time information according to the water pressure And the control unit 1100 controls the dissolving time of the regenerant in the regenerator 700 by controlling the valves in the water softener described above.

For a more detailed description, referring to FIG. 8, FIG. 8 is a flowchart of a method for maintaining a salt water salinity according to the present invention.

(A) measuring a temperature and a water pressure of the regeneration cold water supplied to the regeneration tank 700 by the flow temperature sensor 520 (S100); (b) a step S200 of inputting the temperature and the water pressure of the regeneration cold water measured by the flow rate temperature sensor 520 to the control unit 1100; (c) The control unit 1100 reads the temperature of the regeneration cold water and the dissolution time of the regenerant according to the water pressure from the database (DB) storing the regeneration agent dissolution time information corresponding to the regeneration cold water temperature and water pressure (S300) in which the dissolution time of the regenerant is calculated; And (d) dissolving the regenerant in the regenerator with the cold water for regeneration during the dissolving time of the regenerant calculated in the step (c) (S400); And the dissolution time of the regenerant is controlled so that the salinity of the regenerated water discharged from the regenerator 700 is kept constant.

In operation (a), the cold water valve 190 and the regeneration supply valve 590 are opened, and the cold water valve 190 and the regeneration supply valve 590 are opened. The rinse valve 890 is closed to supply the regeneration cold water to the regenerator 700. [

Thereafter, in the step (d), the regeneration supply valve 590, which was opened in the step (a), is closed to block the regeneration cold water supplied to the regeneration reactor 700, , The regenerant is dissolved in the cold water for regeneration.

On the other hand, the regenerant is formed of a reclaiming block of salt. Considering the solubility of the salt, the higher the temperature of the regeneration cold water supplied into the regenerator 700, the greater the dissolution amount of the regenerating block. The higher the water pressure of the cold water for regeneration, the greater the dissolution amount of the regeneration block.

That is, the higher the temperature and the water pressure of the regeneration cold water supplied into the regeneration tank 700, the greater the dissolution amount of the regeneration block. In order to keep the salinity of the regeneration water constant, .

In this case, the regenerant dissolution time in the step (e) may be set such that the regeneration cold water for dissolving the regenerant during the regenerant dissolution time on the basis of the time when the regeneration cold water is supplied to the regenerator 700 .

In step (a), the regeneration cold water supplied to the regenerator 700 is regulated by the controller 1100, and the amount of regeneration cold water, which is confirmed by the flow temperature sensor 520, When the determined amount is reached, the controller 1100 controls the valve to shut off the regeneration cold water supplied to the regenerator 700.

The time for which the regeneration cold water is filled in the regenerator 700 varies depending on the supply pressure of the regeneration cold water and the regeneration cold water has an inlet pressure of 0.7 kgf / Cm < 2 >, it takes 68 seconds, and it takes 38 seconds when the inlet water pressure of the regeneration cold water is 2.5 kgf / cm < 2 >.

At this time, even when the inlet water pressure of the cold water for regeneration exceeds 2.5 kgf / cm 2, the time required to fill the regenerator 700 is kept constant at 38 seconds.

This is because the above-described pressure reducing valve 120 prevents the intake water pressure of the regeneration cold water from exceeding 2.5 kgf / cm < 2 >, so that the dissolution time at the water supply pressure of the regeneration cold water of 2.5 kgf / It is formed differently depending on the input pressure of the cold water.

However, the set value of the pressure reducing valve 120 and the capacity of the regenerator 700 may be differently formed according to the designer's choice.

The method for maintaining the salt water salinity according to the present invention is preferably to maintain the salinity of the water to be regenerated at 9%. For this purpose, the dissolving amount of the regeneration block should be 200 g in one regeneration. However, the salinity of the regenerated water and the dissolution amount of the regenerating block in one regeneration may vary depending on the preference of the user and the designer's choice.

In Experimental Example 1, when the water temperature for regeneration cold water is 5 ° C. to 15 ° C. and the water temperature for regeneration cold water is 2.5 kgf / cm 2, if the dissolving time is 150 seconds, Was formed to 9%.

(Experimental Example 2) In the case where the water temperature for regeneration cold water was 5 占 폚 to 15 占 폚 and the water pressure for regeneration cold water was 0.7 kgf / cm2, when the dissolving time was 160 seconds, the salinity of regenerated water was 9%.

(Experimental Example 3) In the case where the water temperature for regeneration cold water was 15 占 폚 to 20 占 폚 and the water pressure for regeneration cold water was 2.5 kgf / cm2, when the dissolving time was 95 seconds, the salinity of regenerated water was 9%.

As can be seen from the above experimental examples, the salinity of the regenerated water can be kept constant at 9% by forming the dissolution time differently according to the temperature and pressure of the cold water for regeneration.

In addition, the size of the regenerant is reduced in accordance with the regenerating time of the regenerant, and consequently, the contact area of the regenerant and the regenerating cold water is reduced, so that the dissolving time can be determined by taking the regeneration time as an additional variable.

2.2-2 Playback phase

On the other hand, when the dissolution time has elapsed (C13), the process proceeds to the regeneration step. It is started by closing the opened cold water valve 190 and opening the closed cold water rinse valve 890.

The cold water rinse valve 890 is opened to lower the pressure of the cold water tank 200 and the regenerated water (i.e., cold water regenerated water) flows through the regenerator passage 680, the cold water regeneration water passage 640, and the filter unit 220 And is supplied to the cold water ion exchange resin 230 for a regeneration time at a constant rate.

The supplied cold water regenerated water regenerates the cold water ion exchange resin 230 and is discharged to the outside through the drain 820 through the cold water rinsing water outlet channel 810. It is preferable to be performed for about 20 minutes of regeneration time, but the time is variable.

When all of the regeneration time has elapsed (C14), the process proceeds to the rinsing step. And is started by opening the cold water valve 190 that has been closed. Cold water is received at the cold water inlet 110 and enters the cold water ion exchange resin 230 through the filter 220 to rinse it. And then discharged through the drain 820 through the cold water rinse water outlet 810 due to the opened cold water rinse valve 890. Preferably about 3 minutes, but the time may vary.

(C2) The hot water tank regeneration mode will be described first. (C21) regeneration cold water supply step, (C22) dissolution step, (C23) hot water air removal step, (C24) regeneration step, and (C25) rinsing step. (C1) Compared with the cold water tank regeneration mode, the (C23) hot water air removing step is added.

(C21) The regeneration cold water supply step is generally performed after the (C14) rinsing step. In the rinsing stage where the cold water valve 190, the hot water valve 290 and the cold water rinse valve 890 are opened and the regeneration supply valve 590 and the hot water rinse valve 990 are closed (C14) (590) and closing the cold water rinse valve (890).

(C22) The dissolution step is the same as the dissolution step (C12). When the amount of regeneration cold water detected by the flow rate temperature sensor 520 reaches a predetermined amount (C22), the process proceeds to the dissolving step. Is started by closing the regeneration supply valve 590 that has been opened, and has a dissolving time for melting the regeneration block (not shown). Similarly, the dissolving time can be determined differently depending on the temperature, the flow rate, and the like of the cold water for regeneration.

When the dissolution time has elapsed (C23), the process proceeds to the hot water air removing step. (C1) Unlike the cold water tank regeneration mode, air removal is necessary in the (C2) hot water tank regeneration mode. In the case of the cold water tank 200, since some of the cold water is supplied to the regenerator 700 through the regeneration flow path 500, the hot water tank 400 does not have such a flow path, and it is effective to remove the air and supply the regenerated water to be. For this purpose, the hot water rinse valve 990 is opened for about 10 seconds. In this case, the hot water tank 400 and the air on the associated flow path are discharged to the outside through the drain 820.

On the other hand, since the dissolution may continue in the regenerator 700 even during the (C23) hot air removing step, it is preferable that the time during which the dissolving step (C22) is performed is taken into account in the time of the (C23) hot air removing step. In other words, (C23) the hot water air removal step is performed at the same time as the dissolution step (C22), but the hot water removal step (C23) is performed at the point where the predetermined hot water removal time remains within the predetermined dissolution time. For example, if the (C23) hot air removal step is performed for 10 seconds, (C23) the hot air removal step is started at (C23) when the dissolution time in the dissolution step is 10 seconds.

Now, proceed to the reproduction step (C24). Is started by closing the opened hot water valve 390 and opening the closed hot water rinse valve 990. The hot water regeneration water is supplied to the hot water ion exchange resin 430 via the regenerator flow path 680, the hot water regenerating water path 665 and the filter unit 420 and the hot water ion exchange resin 430 And then discharged to the outside through the drain 820 through the hot water rinse outflow path 910. [ It is preferable to be performed for about 20 minutes of regeneration time, but the time is variable.

When all of the regeneration time has elapsed (C25), the process proceeds to the rinsing step. And is started by opening the closed hot water valve 390. (C14) In the same manner as in the rinsing step, the hot water is taken in the hot water inlet 310 and enters the hot water ion exchange resin 430 through the filter 420 to rinse it. And then discharged through the drain 820 through the hot water rinse outflow path 910 due to the opened hot water rinse valve 990. Preferably about 3 minutes, but the time may vary.

Thus, when both the (C1) cold water tank regeneration mode and the (C2) hot water tank regeneration mode are performed, (D) the regeneration regeneration mode is performed to rinse the regenerator 700.

2.3 Playback mode

(D) The regenerating mode is (D1) cold water supplying step for rinsing. (D2) regenerator drain stage, (D3) cold water rinse stage, and (D4) hot water rinse stage.

(D1) The cold water supply step for rinsing is a step of supplying cold water for washing the regenerator 700 in a state where all regeneration blocks (not shown) located in the regenerator 700 are dissolved. (C2) When the hot water tank regeneration mode is completed, the cold water valve 190, the hot water valve 290 and the hot water rinse valve 990 are opened and the regeneration supply valve 590 and the cold water rinse valve 890 are closed, The regeneration supply valve 590, which has been opened and closed, is opened. Accordingly, the cold water supplied through the cold water inlet 110 flows through the filter unit 220 and flows toward the regeneration cold water inlet passage 510 due to the opening of the regeneration supply valve 590, (530) and the inlet channel (610) and is supplied to the regenerator (700). The flow rate supplied at this time is enough to fill only a part of the regenerator 700. For example, if 1.5 liters are supplied in steps (C11) to (C12), only 0.5 liters can be supplied in step (D11).

Next, a regenerator drain step (D12) is performed. The opened cold water valve 190 and the regeneration supply valve 590 are closed and the cold water rinse valve 890 which has been closed is opened to drain the remaining water in the regenerator 700. [

Next, (D13) cold water rinsing step is performed. In the step of rinsing the cold water tank 200, the cold water valve 190 that has been closed is opened to introduce cold water into the cold water tank 200, and rinses the cold water to drain the cold water.

Next, (D14) a hot water rinse step is performed. In the step of rinsing the hot water tank 400, hot water is introduced into the hot water tank 400 by opening the closed hot water valve 390 and rinsed to drain it.

Ions are supplied to both the cold water ion exchange resin 230 and the hot water ion exchange resin 430 and the regenerator 700 and the cold water tank 200 And the hot water tank 400 are all rinsed up, and are ready to supply the user with the training water again.

Now, (B) return to the training mode. To this end, when the hot water rinse valve 990 opened in step (D14) is closed, only the cold water valve 190 and the hot water valve 390 are opened as in the (B) training mode.

While the present invention has been described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. It will be appreciated that embodiments are possible. Accordingly, the scope of protection of the present invention should be determined by the claims.

100: cold water intake part
110: Cold water intake route
120: Pressure reducing valve
130: Flow sensor
190: cold water valve
200: cold water tank
210: cold water supply channel
220:
221: Filter cover
230: cold water ion exchange resin
240: cold water outlet
300: Hot water intake part
310: Hot water intake route
320: Pressure reducing valve
330: Flow sensor
390: Hot water valve
400: Hot water tank
410: Hot water supply channel
420:
421: Filter cover
430: Hot water ion exchange resin
440: Hot water outlet
500: Playing Euro
510: cold water for regeneration
520: Flow temperature sensor
530: Connector intake channel
590: regeneration supply valve
600: Connector
610: Incoming route
640: Cold water reclaimed water
645: Check valve
660: Hot water
665: Check valve
680:
700: Regenerator
800: cold water drain
810: Cold water rinse heading
820: drain
890: Cold water rinse valve
900: Hot water drain
910: Hot water rinse heading
990: Hot water rinse valve
1010: upper cover
1011: Control panel
1020: Lower cover
1021: Performance indicator
1022: Display during reproduction
1023: Battery indicator
1100:

Claims (12)

A regeneration water salinity holding method in a regenerator of a water softener,
(a) measuring a temperature and a water pressure of regeneration cold water supplied to the regeneration cylinder 700 by the flow temperature sensor 520 (S100);
(b) a step S200 of inputting the temperature and the water pressure of the regeneration cold water measured by the flow rate temperature sensor 520 to the control unit 1100;
(c) The control unit 1100 reads the temperature of the regeneration cold water and the dissolution time of the regenerant according to the water pressure from the database (DB) storing the regeneration agent dissolution time information corresponding to the regeneration cold water temperature and water pressure (S300) in which the dissolution time of the regenerant is calculated; And
(d) dissolving the regenerant in the regenerator 700 with the regeneration cold water during the dissolving time of the regenerant calculated in the step (c) (S400); / RTI >
The regeneration time of the regenerant is controlled to maintain the salinity of the regeneration water discharged from the regeneration tank 700 constant,
A method of maintaining salinity of a reclaimed water.
The method according to claim 1,
The step (d)
(d-1) In the control unit 1100, when the regenerant dissolution time elapses, regeneration water in the regenerator 700 is supplied to the cold water tank 200 or the hot water tank 400 in which the ion exchange resin is embedded Controlling the valve (S420); ≪ / RTI >
A method of maintaining salinity of a reclaimed water.
The method according to claim 1,
The regenerant dissolution time in the step (e)
Wherein the regeneration cold water dissolves the regenerant during the regenerant dissolution time on the basis of a time when the regeneration cold water is supplied to the regenerator (700)
A method of maintaining salinity of a reclaimed water.
The method according to claim 1,
In the step (a), the water pressure of the cold water for regeneration is calculated by the flow rate of the cold water for regeneration,
A method of maintaining salinity of a reclaimed water.
The method according to claim 1, wherein the salinity of the regenerated water discharged from the regenerator (700) is 9%
A method of maintaining salinity of a reclaimed water.
The method according to claim 1,
In the step (b), the number of times of reproduction is further input,
In the step (c), the controller 1100 reads the temperature of the regeneration cold water, the pressure of the regeneration cold water from the database (DB) storing the regeneration agent dissolution time information according to the regeneration cold water temperature, The dissolving time of the regenerant is calculated by loading the dissolving time of the regenerant according to the difference,
A method of maintaining salinity of a reclaimed water.
The method according to claim 1,
In the step (a)
The regeneration cold water supplied to the regeneration tank 700 is regulated by the control unit 1100. When the amount of regeneration cold water identified by the flow rate temperature sensor 520 reaches a predetermined amount, (1100) controls the valve to block the regeneration cold water supplied to the regenerator (700)
A method of maintaining salinity of a reclaimed water.
3. The method of claim 2,
The water softener
A regeneration flow path 500 communicating with the cold water receiving portion 100; And
A connector 600 for supplying cold water for regeneration to the regeneration tank 700 and supplying regeneration water to the cold water tank 200 or the hot water tank 400 in the regeneration tank 700, ), ≪ / RTI >
A method of maintaining salinity of a reclaimed water.
9. The method of claim 8,
The water softener
The cold water receiving unit 100;
The cold water tank 200 for supplying cold water to the regeneration flow path 500 as cold water for regeneration while receiving cold water from the cold water receiving part 100 and exiting the water by ion exchange;
A hot water receiving unit 300;
The hot water tank 400 receives hot water from the hot water receiving unit 300 and ion-exchanges the hot water.
The regenerator (700);
A cold water drain (800) having one end connected to the cold water tank (200) and the other end connected to the drain (820);
A hot water drain (900) having one end connected to the hot water tank (400) and the other end connected to the drain (820);
A cold water valve 190 located in the cold water inlet 100;
A hot water valve 390 located in the hot water receiving part 300;
A regeneration supply valve 590 located in the regeneration passage 500;
A cold water rinse valve 890 located in the cold water drain 800; And
Further comprising a hot water rinse valve (990) located in the hot water drain (900)
In the step (a), the cold water valve 190 and the regeneration supply valve 590 are opened, and the cold water rinse valve 890 is closed, thereby supplying the regeneration cold water to the regenerator 700.
A method of maintaining salinity of a reclaimed water.
10. The method of claim 9,
In the step (d), the regeneration supply valve 590, which was opened in the step (a), is closed to block the regeneration cold water supplied to the regeneration reactor 700, Through which the regenerant is dissolved,
A method of maintaining salinity of a reclaimed water.
11. The method of claim 10,
In the step (d-1), the cold water valve 190 is closed and the cold water rinse valve 890 is opened to supply the regenerated water to the cold water tank 200,
A method of maintaining salinity of a reclaimed water.
11. The method of claim 10,
In the step (d-1), the hot water valve 390 is closed and the hot water rinse valve 990 is opened to supply the regenerated water to the hot water tank 400,
A method of maintaining salinity of a reclaimed water.

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