KR102642328B1 - Method for Performing Care Mode and Softener Compring Thereof - Google Patents

Abstract

The present invention provides a method of performing a care mode for a water softener, comprising: (a) blocking the supply of raw water from a faucet to the water softener (S100); and (b) draining the flow path to release the pressure formed in the flow path inside the water softener (S200); Provides a method of performing a care mode, including.

Description

Method for performing care mode of water softener and water softener including the same {Method for Performing Care Mode and Softener Compring Thereof}

The present invention relates to a method of performing a care mode for a water softener and a water softener including the same. Specifically, it relates to the operation of internal components of the water softener during the care mode performed to replace and maintain parts of the water softener.

Tap water (hereinafter referred to as “hard water”) contains a large amount of chlorine ions during the purification process, and when it passes through old pipes or when the raw tap water itself is severely contaminated, it contains iron, zinc, lead, mercury, etc., which are harmful to the human body. Contains various heavy metal ions.

These heavy metal ions, in particular, can combine with the fatty acids of soap to create metallic foreign substances, which can cause allergies or skin aging when in contact with the skin.

To prevent this, hard water is passed through strong acidic cations such as sodium ions (Na+), and calcium ions (Ca2+) and magnesium ions (Mg2+), which are hardness components, are exchanged with sodium ions (Na+), thereby reducing calcium, which is a hardness component. Soft water from which ions (Ca2+) and magnesium ions (Mg2+) have been removed can be produced, and many homes use water softeners to convert hard water into soft water.

In order to exchange calcium ions (Ca2+) and magnesium ions (Mg2+), which are hardness components, with sodium ions (Na+), the water softener is equipped with an ion resin tank that stores water containing sodium ions (Na+), and the ions The resin tank consists 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, the sodium ions (Na+) in the hot water tank and the cold water tank are continuously consumed, so sodium is added to the hot water tank and the cold water tank at regular intervals. It is necessary to replenish ions (Na+).

For this purpose, the water softener is provided with a regeneration tank, generates regenerated water containing sodium ions (Na+) in the regeneration container, and then supplies the regenerated water to the hot water tank and the cold water tank to replenish the sodium ions (Na+). .

Specifically, a basket is provided in the regeneration tank, and the basket has a regenerant built in, and raw water flowing into the regeneration tank dissolves the regenerant, thereby generating recycled water.

Meanwhile, the water softener includes consumable parts scheduled for replacement. For example, representative examples include filters that filter raw water flowing into cold water tanks and hot water tanks, and regenerants that must be periodically filled to generate reclaimed water.

Generally, replacement of these consumables requires periodic inspection by the manager, and upon inspection by the manager, the inspection is performed after stopping the operation of the water softener.

In this regard, Korean Application No. 20-2004-0022715, which is a prior art, discloses a water softener in which the cover constituting the case is formed to be easily attached and detached from the main body.

Specifically, the prior art is described as having the effect of improving the convenience of service by forming the cover constituting the case to be easily attached and detached from the main body using a magnet.

However, the prior art only discloses the structure of the water softener, the process of regenerating the water softener, and the process of supplying soft water, but does not disclose at all the specific operation in the process of inspecting the water softener.

Conventionally, it can be seen that inspection of the water softener is performed only after turning off the power to the water softener. As the current inside the water softener is cut off, malfunction of the valve opening and closing may occur, and the manager must forcibly stop the operation of the water softener. When needed, there was the inconvenience of having to open and close the valves individually.

Accordingly, there is a very high need for technology that increases the convenience of managers' work when inspecting a water softener or forcibly stopping the water softener.

(Patent Document 1) Korean Patent Publication No. 20-2004-0022715

The present invention was created to solve the above problems.

Specifically, we would like to propose a method of creating a state in which the manager can inspect the water softener only by operating the valves provided in the flow path inside the water softener.

In addition, we would like to propose a method in which it is unnecessary to turn off the water softener power supply for inspection, and the care mode in which the water softener inspection is performed is connected to the regeneration mode or soft water mode while maintaining the water softener power supply as is.

One embodiment of the present invention to solve the above problems is a method of performing a care mode for a water softener, comprising: (a) blocking the supply of raw water from the faucet to the water softener (S100); and (b) draining the flow path to release the pressure formed in the flow path inside the water softener (S200); Provides a method of performing a care mode, including.

In addition, after step (b), (c) the manager performs a maintenance process for the water softener, including replacing the battery or regenerant provided inside the water softener (S300); It is desirable to further include.

Additionally, the water softener includes a care button; a first valve controlling the supply of raw water from the water tap to the water softener; a second valve controlling drain of the water softener internal flow path; and a control unit 1100 configured to control the operation of the first valve and the second valve. It includes, before step (a), (a0) pressing the care button (S10); It further includes, when the care button is pressed, in step (a), the control unit 1100 closes the first valve, and in step (b), the control unit 1100 closes the second valve. It is desirable to be open.

Additionally, in step (a0), when the care button is pressed, it is preferable that the performance display unit 1021 formed on the outer surface of the water softener displays that the care mode is currently being performed.

In addition, the water softener includes a cold water tank 200; hot water tank (400); Flow sensors 130 and 330 that check the total cumulative flow rate flowing into the cold water tank 200 and the hot water tank 400 in real time, respectively; and a timer 1110 that checks in real time the elapsed time since the last regeneration of the cold water tank 200 and the hot water tank 400 was performed. Further comprising, in step (a0), when the care button is pressed, the total accumulated flow rate of the flow sensors 130, 330 and the elapsed time from the time when the last playback of the timer 1110 was performed are initialized. It is advisable to stop.

In addition, after step (c), when the care mode is completed and the care mode is released, the total accumulated flow rate of the flow sensors 130, 330 and the time when the timer 1110 was last played are calculated. It is desirable for the elapsed time calculation to proceed again from an initialized value.

In addition, the water softener includes a cold water intake unit 100; A cold water tank (200) that receives cold water from the cold water intake unit (100), performs ion exchange, and discharges the water; Hot water intake unit (300); A hot water tank (400) that receives hot water from the hot water intake unit (300), exchanges ions, and discharges hot water; A cold water drain (800) whose one end is connected to the cold water tank (200) and the other end is connected to a drain (820); a hot water drain (900) with 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 intake unit 300; A regeneration supply valve 590 located in the regeneration flow path 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 first valve is the cold water valve 190 and the hot water valve 390, and the second valve is the cold water rinse valve. The valve 890 and the hot water rinse valve 990 are preferably used.

In addition, 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 all latch valves, and the control unit 1100 ) It is preferable that the opening and closing is operated by an electrical signal generated from the.

In addition, the control unit 1100, cold water valve 190, hot water valve 390, regeneration supply valve 590, cold water rinse valve 890, and hot water rinse valve 990 are all batteries provided inside the water softener. It is desirable to operate with power supply.

In addition, a battery display unit 1023 is formed on the outer surface of the water softener to display the remaining amount of the battery, and the battery display unit 1023 provides a battery replacement alarm when the displayed remaining battery amount is below a predetermined value. It is desirable to display .

The present invention can prevent moisture from penetrating into the electric circuit and electronic devices inside the water softener by blocking the supply of raw water to the water softener and draining the flow path within the water softener to release the pressure formed in the flow path when the manager performs the care mode. there is.

In addition, to accomplish this, when the care mode is performed, the control unit automatically closes the first valve that controls the supply of raw water to the water softener and opens the second valve that controls the drain of the water softener's internal flow path, allowing the manager to individually This eliminates the need to open and close the valve, increasing the convenience of the manager.

In addition, when performing the care mode, the total accumulated flow rate and timer flowing into the cold water tank and hot water tank are automatically reset, so there is no need to turn off the water softener power and there is no need for the administrator to manually initialize it. Intervention was kept to a minimum.

1 is a perspective view showing the exterior of a water softener according to the present invention.
Figures 2 and 3 are perspective views showing the water softener according to the present invention, with the upper and lower covers removed and the frame and some connecting parts omitted for illustration purposes. As can be seen in the coordinate system, Figure 2 is It is a perspective view viewed from the front lower side, and Figure 3 is a perspective view viewed from the rear upper side.
Figure 4 is a perspective view showing a connector of a water softener according to the present invention.
Figure 5a is a diagram schematically showing the flow path of a water softener according to the present invention.
Figure 5b is a diagram schematically showing a flow path through which cold water for regeneration is supplied (steps C11 and C21 below) in the water softener according to the present invention.
Figure 5c is a diagram schematically showing a flow path (step C13 below) for supplying reclaimed water to a cold water tank in the water softener according to the present invention.
Figure 5d is a diagram schematically showing a flow path (step C24 below) that supplies reclaimed water to a hot water tank in the water softener according to the present invention.
Figure 6 is a diagram for explaining the operating mode of the water softener according to the present invention and the operation of the valve accordingly.
Figure 7 is a block diagram of a method of performing a care mode according to the present invention.
Figure 8 is a flowchart of a care mode performance method according to the present invention.

Hereinafter, “cold water” and “hot water” refer to fluids individually supplied to the water softener from the cold water faucet and the hot water faucet, respectively.

“Recycled water” refers to a fluid in which recycling blocks, which may be salt, for example, are dissolved to supply ions to the ion exchange resin. When “reclaimed water” is supplied to a cold water tank, it is referred to as “cold water regenerated water,” and when supplied to a hot water tank, it is referred to as “hot water regenerated water.”

“Cold water for recycling” means cold water supplied to generate recycled 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.

Figure 1 shows the exterior of a water softener according to the present invention, showing an upper cover 1010 and a lower cover 1020. For explanation purposes, the upper cover 1010 is shown transparently.

The recycle bin 700 is located on the inner upper part of the upper cover 1010, and the filter cover 221 of the cold water tank 200 and the filter cover 421 of the hot water tank 400 are located at the bottom of the recycle bin 700. The upper cover 1010 is removed to replace the filter or fill the recycling container 700 with a recycling block (not shown).

A control panel 1011 is located inside the upper cover 1010. The control panel 1011 includes a notification window that displays the number of playbacks, and an input unit for inputting current time settings, playback settings, care mode, and manual playback.

The lower cover 1020 protects the inner flow path.

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

2 and 3 show a water softener with the upper cover 1010 and lower cover 1020 removed. For explanation purposes, the frame and connecting parts for fixing each part to the frame are omitted.

Figure 4 shows the connector 600, and Figures 5a to 5d schematically show the flow path. In FIGS. 2 and 3, the tube to which each component is connected is omitted, but the connection method can be confirmed by referring to the description below and 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 Cold water inlet (100)

The water softener according to the present invention includes a cold water inlet 100, a cold water tank 200, a hot water inlet 300, a hot water tank 400, a regeneration passage 500, a connector 600, a regeneration tank 700, It includes a cold water drain (800) and a hot water drain (900).

The cold water intake unit 100 is located at the bottom of the water softener and is connected to a cold water tap (not shown) to supply cold water, which is raw water, to the water softener. It includes a cold water inlet 110, a pressure reducing valve 120, a flow sensor 130, and a cold water valve 190.

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

The cold water valve 190 is provided between the cold water inlet 110 and the cold water inlet passage 210 and controls whether cold water flows in. The cold water valve 190 is controlled according to the operating mode, and 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 intake unit 100 and supply it to the regeneration tank 700 as cold water for discharge or recycling. It includes a cold water inlet flow path 210, a filter unit 220, a cold water ion exchange resin 230, and a cold water outlet 240.

The cold water inlet flow path 210 is connected to the cold water inlet 110, and as shown in FIGS. 2 and 3, is provided in the center of the cold water tank 200 and is filled with cold water ion exchange resin 230 to surround it. It can be. Cold water flowing in through the cold water intake flow path 210 rises.

The filter unit 220 is located at the end of the cold water inlet flow path 210, and the cold water supplied through the cold water inlet flow path 210 is filtered in the filter part 220. The user can replace the filter by opening the filter cover 221 of the cold water tank 200.

The cold water that has passed through the filter unit 220 flows radially outward and then descends, or is supplied as cold water for regeneration through the cold water inlet for regeneration 510, which is a tube (see FIGS. 5A to 5D). Some flows to the cold water reclaimed water outlet 640 containing another tube, but does not flow to the connector 600 due to the check valve 645, but only maintains the hydraulic pressure in the flow path.

The cold water that flows radially outward through the filter unit 220 and then passes through the cold water ion exchange resin 230 and descends is softened by the ion exchange action. Softened cold water is discharged to the user through the cold water outlet 240.

1.3 Hot water inlet (300)

The hot water intake unit 300 is located at the bottom of the water softener and is connected to a hot water tap (not shown) to supply hot water, which is raw water, to the water softener. It includes a hot water inlet 310, a pressure reducing valve 320, a flow sensor 330, and a hot water valve 390.

Likewise, the hot water inlet 310 is connected to the hot water inlet to receive hot water, the supplied hot water passes through the pressure reducing valve 320, the pressure is reduced, and the flow rate of the supplied hot water is confirmed by the flow rate sensor 330.

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

1.4 Hot water tank (400)

The hot water tank 400 serves to soften the hot water supplied from the hot water intake unit 300 and discharge it. Unlike the cold water tank 200, hot water is not supplied to the regeneration tank 700. It includes a hot water inlet flow path 410, a filter unit 420, a hot water ion exchange resin unit 430, and a hot water outlet 440.

The hot water intake flow path 410 is connected to the hot water intake unit 310, and as shown in Figures 2 and 3, is provided in the center of the hot water tank 400 and is filled with hot water ion exchange resin 430 to surround it. It can be. The hot water flowing in through the hot water intake flow path 410 rises.

A filter unit 420 is located at the end of the hot water intake flow path 410, and hot water supplied through the hot water intake flow path 410 is filtered in the filter unit 420. The user can replace the filter by opening the filter cover 421 of the hot water tank 400.

The hot water that has passed through the filter unit 420 flows radially outward and then descends, but unlike the cold water tank 200, it is not supplied to the regeneration passage 500. Some flows into the hot water reclaimed water outlet 660 including the tube, but does not flow to the connector 600 due to the check valve 665, but only maintains hydraulic pressure within the flow path.

The hot water that flows radially outward through the filter unit 420 and then passes through the hot water ion exchange resin 430 and descends is softened by the ion exchange action. Softened hot water is discharged to the user through the hot water outlet 440.

1.5 Renewable Euros (500)

The recycling passage 500 serves to supply cold water supplied through the cold water intake unit 100 and the cold water tank 200 to the recycling tank 700 through the connector 600 as cold water for recycling to generate recycled water. It includes a regeneration cold water inlet 510, a flow temperature sensor 520, a connector inlet 530, and a regeneration supply valve 590.

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

A regeneration supply valve 590 and a flow temperature sensor 520 are provided in the cold water inlet 510 for regeneration. The regeneration supply valve 590 is controlled according to the operating mode, details of which will be described later. The flow rate and temperature of cold water for regeneration sensed by the flow rate temperature sensor 520 can be used to determine the number of regeneration and regeneration time.

1.6 Connector(600)

The connector 600 supplies cold water for recycling supplied from the recycling passage 500 to the recycling tank 700, and delivers the reclaimed water generated in the recycling tank 700 to the cold water tank 200 and the hot water tank 400. It plays a role. The inlet channel 610, the cold water regeneration water outlet channel 640 and the check valve 645 provided therein, the hot water regeneration water outlet channel 660 and the check valve 665 provided therein, and the regeneration tank 700 are in communication with each other. Includes regeneration tank flow path (680).

The water inlet 610 is connected to the connector inlet 530, and cold water for recycling is supplied to the regeneration tank 700 through it.

A regeneration tank 700 is connected to one end of the cold water regeneration water outlet channel 640 and the other end is connected to the cold water tank 200. In normal times, the passage from the check valve 645 to the cold water tank 200 in the cold water regeneration water outlet 640 is filled with cold water to maintain a constant hydraulic pressure. As described above, cold water is not delivered to the regeneration tank 700 due to the check valve 645. During regeneration, cold water regeneration water is supplied from the regeneration tank 700 to the cold water tank 200 through the cold water regeneration water outlet 640.

Likewise, the regeneration tank 700 is connected to one end of the hot water reclaimed water outlet path 660 and the other end is connected to the hot water tank 400. In normal times, the flow path from the check valve 665 to the hot water tank 400 in the hot water reclaimed water outlet path 660 is filled with hot water, so a constant hydraulic pressure is maintained, and the hot water is delivered to the reclaimed water tank 700 due to the check valve 665. It doesn't work. During regeneration, hot water regeneration water is supplied from the regeneration tank 700 to the hot water tank 400 through the hot water regeneration water outlet 660.

Normally (i.e., (B) soft water mode, described later), cold water passes through the filter unit 220 and is filled up to the check valve 645 of the cold water regeneration water outlet 640, and hot water passes through the filter unit 420 and is filled with hot water. The check valve 665 of the reclaimed water outlet 660 is filled. In the water softener according to the present invention, the cold water tank 200 and the hot water tank 400 have a structure that can communicate through the cold water reclaimed water outlet 640 and the hot water reclaimed water outlet 660, using check valves 645 and 665. This prevents mixing in normal times. As will be described later, due to the check valves 645 and 665, recycled water generated in one recycling tank 700 can be supplied to both the cold water tank 200 and the hot water tank 400.

One end of the regeneration tank flow path 680 is connected to the regeneration container 700, and the other end is connected to all three flow paths, namely the inlet channel 610, the cold water regeneration water outlet channel 640, and the hot water regeneration water outlet channel 660. . When supplying cold water for regeneration, the cold water for recycling passes through the water inlet 610 and the regeneration conduit passage 680, and in the drawing, the cold water for regeneration flows upward within the regeneration conduit passage 680. On the other hand, cold water regeneration water passes through the regeneration tank flow path 680 and the cold water regeneration water outlet conduit 640, and hot water regeneration water passes through the regeneration container flow path 680 and the hot water regeneration water outlet conduit 660, and in the drawing, the regeneration container flow path 680 ) flows downward within.

1.7 Recycling bin (700)

The recycling tank 700 receives cold water for recycling from the connector 600 and generates recycling water.

The recycling bin 700 may be filled with recycling blocks (not shown). When the cold water for regeneration passes through the cold water inlet 110, the cold water inlet flow path 210, the filter unit 220, the cold water inlet for regeneration 510, and the water inlet 610 and is supplied to the regeneration tank 700, it is recycled. As the melting block (not shown) melts, recycled water is generated.

Here, the cold water regeneration water and the hot water regeneration water are the same regeneration water generated in the regeneration tank 700 and are divided depending on whether it is supplied to the cold water tank 200 or the hot water tank 400. That is, some of the reclaimed water generated in the regeneration tank 700 is supplied to the cold water tank 200 through the cold water reclaimed water outlet 640 of the connector 600. At this time, the supplied reclaimed water is cold water reclaimed water, and the other portion is supplied through the connector 600. It is supplied to the hot water tank 400 through the hot water reclaimed water outlet 660 of 600, and the reclaimed water supplied at this time is hot water reclaimed water. Generally, cold reclaimed water is first supplied to the cold water tank 200, and then hot reclaimed water is supplied to the hot water tank 400.

When cold water regeneration water flows 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.

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

In addition, the lower end of the regeneration tank 700 may be connected to the drain 820 by a tube so that the recycled water or rinsed water that overflows from the regeneration tank 700 is discharged through the drain 820, which will be described later. there is.

1.8 Cold water drain (800)

The cold water drain 800 serves to drain water rinsing the cold water tank 200. It includes a cold water rinse outlet 810, a drain 820, and a cold water rinse valve 890.

One end of the cold water rinse outlet 810 is connected to the cold water tank 200 by a tube, 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 to the outside of the water softener.

1.9 Hot water drain (900)

The hot water drain 900 serves to drain water rinsing the hot water tank 400 through the drain 820. It includes a hot water rinse outlet 910 and a hot water rinse valve 990.

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

2. Description of the operating modes of the water softener

The operating mode of the water softener according to the present invention will be described with reference to FIG. 6.

The operating mode of the water softener according to the present invention can be divided into (A) raw water mode, (B) soft water mode, (C) regeneration mode, and (D) regeneration tank rinse mode.

Each mode can be implemented through control of five valves, that is, 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. Conventional water softeners generally used a single multi-way valve including a ceramic disc, but due to the nature of water softeners operating in a humid environment, malfunctions were frequent, which became the main cause of water leaks or defects. The present invention provides 5 The operating mode was implemented by dividing the valves.

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

(A) Raw water mode is an operating mode when the user uses raw water rather than soft water, and detailed explanations are omitted.

2.1 Training mode

(B) Soft water mode is when the user uses soft water, opens the cold water valve 190 and the hot water valve 390, and opens the regeneration supply valve 590, cold water rinse valve 890, and hot water rinse valve 990. It is implemented by closing .

Since the cold water valve 190 is open and the regeneration supply valve 590 is closed, the cold water supplied through the cold water inlet 110 does not flow to the regeneration passage 500 after passing through the filter unit 220 and cold water ions It passes through the exchange 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 is discharged through the cold water outlet 240 as much as the user wants.

The same goes for hot water.

2.2 Play mode

(C) In the regeneration mode, when the ions of the cold water ion exchange resin 230 in the cold water tank 200 and the hot water ion exchange resin 430 in the hot water tank 400 decrease and it is difficult to produce soft water, regeneration water is supplied to each. This is a mode that regenerates resin. Cold water for regeneration is supplied to the regeneration tank 700 to generate regeneration water, and is then 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 time to start the regeneration mode may be set based on the total flow rate of soft water used by the user, and/or may be set based on the time from the time when the regeneration mode was last performed.

For example, if the user used softened cold water or hot water in excess of the standard flow rate of a total of 600 liters, (C) regeneration mode may be performed. The amount of soft water used can be confirmed through the flow sensor 130 on the cold water side and the flow sensor 330 on the hot water side. If either cold water or hot water exceeds the standard flow rate, it is desirable to regenerate both the cold water tank 200 and the hot water tank 400. This is to prevent the (C) regeneration mode from being used too frequently, which takes about an hour and prevents the user from using the water softener, and to manage the ion exchange resin on the cold and hot water sides in an integrated manner.

At the same time, if 8 days have passed since the last time the playback mode was performed, (C) playback mode can be performed even if the flow rate used by the user does not exceed the standard flow rate. This is to prepare for cases where the flow meter is defective or the function of the ion exchange resin naturally decreases over time.

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

(C1) The cold water tank regeneration mode will be explained first. It consists of (C11) a cold water supply step for regeneration, (C12) a dissolution step, (C13) a regeneration step, and (C14) a rinse step.

(C11) The cold water supply stage for regeneration is generally started by changing from the normally operated (B) soft water mode. For this purpose, the regeneration supply valve is operated in (B) soft water mode where the cold water valve 190 and the hot water valve 390 are open and the regeneration supply valve 590, cold water rinse valve 890, and hot water rinse valve 990 are closed. Only (590) is open. Now, the cold water supplied through the cold water inlet 110 flows toward the cold water inlet 510 for regeneration due to the opening of the regeneration supply valve 590 after passing through the filter unit 220, and the connector inlet 530 ), passing through the water intake passage 610 and the recycling tank flow path 680, is supplied to the recycling container 700. The amount of cold water for recycling supplied to the recycling tank 700 is confirmed by the flow rate temperature sensor 520.

When the amount of cold water for regeneration confirmed by the flow rate temperature sensor 520 reaches a predetermined amount (i.e., the capacity of the regeneration tank 700), the process proceeds to the dissolution step (C12). It begins by closing the open regeneration supply valve 590. Since the regeneration supply valve 590 and the cold water rinse valve 890 are both closed and the pressure is maintained, the regeneration water generated in the regeneration tank 700 does not flow into the cold water tank 200 and has time to dissolve. 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, flow rate, etc. of the cold water for regeneration.

When the dissolution time has elapsed, proceed to the regeneration step (C13). It starts by closing the open cold water valve 190 and opening the closed cold water rinse valve 890. Due to the opening of the cold water rinse valve 890, the pressure on the cold water tank 200 is lowered and the reclaimed water (i.e., cold water reclaimed water) passes through the reclaimed water passage 680, the cold water reclaimed water outlet 640, and the filter unit 220. Cold water is supplied to the ion exchange resin 230 at a constant rate during the regeneration time. The supplied cold water regeneration water regenerates the cold water ion exchange resin 230, passes through the cold water rinse outlet 810, and is discharged to the outside through the drain 820. This is preferably done for a playing time of about 20 minutes, but the time can vary.

When the playback time has elapsed, proceed to the rinse step (C14). It starts by opening the closed cold water valve 190. Cold water is received from the cold water inlet 110, and enters the cold water ion exchange resin 230 through the filter unit 220 to rinse it. Afterwards, due to the opened cold water rinse valve 890, the cold water passes through the cold water rinse outlet passage 810 and is discharged to the outside through the drain 820. It is desirable to do this for about 3 minutes, but the time can vary.

(C2) The hot water tank regeneration mode will be explained first. It consists of (C21) supply of cold water for regeneration, (C22) dissolution step, (C23) hot water air removal step, (C24) regeneration step, and (C25) rinse step. Compared to the (C1) cold water tank regeneration mode, the difference is that (C23) a hot water air removal step is added.

(C21) The cold water supply step for regeneration is generally performed after the (C14) rinse step. In the (C14) rinse step where the cold water valve 190, hot water valve 290, and cold water rinse valve 890 are open and the regeneration supply valve 590 and hot water rinse valve 990 are closed, the regeneration supply valve It begins by opening 590 and closing cold water rinse valve 890.

The (C22) dissolution step is the same as the (C12) dissolution step. When the amount of cold water for regeneration confirmed by the flow temperature sensor 520 reaches a predetermined amount, the process proceeds to the dissolution step (C22). It starts by closing the open regeneration supply valve 590, and has a dissolution time in which the regeneration block (not shown) melts. Likewise, the dissolution time may be determined differently depending on the temperature, flow rate, etc. of the cold water for regeneration.

Once the dissolution time has elapsed, proceed to the hot water air removal step (C23). Unlike (C1) cold water tank regeneration mode, (C2) hot water tank regeneration mode requires air removal. In the case of the cold water tank 200, some of the cold water is supplied to the regeneration tank 700 through the recycling passage 500, whereas the hot water tank 400 does not have such a passage, so it is effective to remove air and supply reclaimed water. am. For this purpose, the hot water rinse valve 990 is opened for about 10 seconds. In this case, the air in the hot water tank 400 and related flow paths is discharged to the outside through the drain 820.

Meanwhile, since dissolution may continue in the regeneration tank 700 even during the (C23) hot water air removal step, it is desirable that the time for the (C22) dissolution step take into account the time of the (C23) hot water air removal step. In other words, the (C23) hot water air removal step is performed simultaneously with the (C22) dissolution step, but the (C23) hot water air removal step is performed when the predetermined hot water air removal time remains among the predetermined dissolution times. For example, if the (C23) hot water air removal step is performed for 10 seconds, the (C23) hot water air removal step starts when 10 seconds remain in the dissolution time in the (C22) dissolution step.

Now, proceed to the playback step (C24). It starts by closing the open hot water valve 390 and opening the closed hot water rinse valve 990. (C13) As in the regeneration step, the hot water regeneration water is supplied to the hot water ion exchange resin 430 through the regeneration tank flow path 680, the hot water regeneration water outlet channel 665, and the filter unit 420. ) is regenerated, and then passes through the hot water rinse outlet 910 and is discharged to the outside through the drain 820. This is preferably done for a playing time of about 20 minutes, but the time can vary.

When the playback time has elapsed, proceed to the rinse step (C25). It starts by opening the closed hot water valve 390. (C14) As in the rinsing step, hot water is received from the hot water inlet 310, enters the hot water ion exchange resin 430 through the filter unit 420, and rinses it. Afterwards, due to the open hot water rinse valve 990, the hot water passes through the hot water rinse outlet 910 and is discharged to the outside through the drain 820. It is desirable to do this for about 3 minutes, but the time can vary.

In this way, when both the (C1) cold water tank regeneration mode and (C2) hot water tank regeneration mode are performed, the (D) regeneration container rinse mode is performed to rinse the regeneration container 700.

2.3 Recycling bin rinse mode

(D) The recycle bin rinse mode includes (D1) a cold water supply step for rinsing, (D2) a recycle bin drain step, (D3) a cold water rinse step, and (D4) a hot water rinse step.

(D1) The cold water supply step for rinsing is a step in which cold water is supplied for cleaning the regeneration container 700 in a state in which all recycling blocks (not shown) located in the regeneration container 700 are dissolved. (C2) When the hot water tank regeneration mode is completed, the cold water valve 190, hot water valve 290, and hot water rinse valve 990 are opened, and the regeneration supply valve 590 and cold water rinse valve 890 are closed. The open hot water rinse valve 990 is closed and the closed regeneration supply valve 590 is opened. Accordingly, the cold water supplied through the cold water inlet 110 flows toward the cold water inlet 510 for regeneration due to the opening of the regeneration supply valve 590 after passing through the filter unit 220, and flows toward the connector inlet. It passes through 530 and the water inlet 610 and is supplied to the recycling bin 700. At this time, the flow rate supplied is sufficient to fill only part of the regeneration tank 700. For example, if 1.5 liters were supplied in steps (C11) to (C12), only 0.5 liters may be supplied in step (D11).

Next, (D12) the recycle bin drain step is performed. The open cold water valve 190 and the regeneration supply valve 590 are closed, and the closed cold water rinse valve 890 is opened to drain the remaining water in the regeneration tank 700.

Next, (D13) a cold water rinse step is performed. In the step of rinsing the cold water tank 200, the closed cold water valve 190 is opened to allow cold water to flow into the cold water tank 200, and then rinsed and drained.

Next, (D14) a hot water rinse step is performed. In the step of rinsing the hot water tank 400, the closed hot water valve 390 is opened to allow hot water to flow into the hot water tank 400, and then rinsed and drained.

When both the (C) regeneration mode and (D) regeneration tank rinse mode are performed, ions are supplied to the cold water ion exchange resin 230 and the hot water ion exchange resin 430, and the regeneration container 700 and the cold water tank 200 ) and the hot water tank 400 have all been rinsed and are ready to supply soft water to the user again.

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

2.4 Care Mode

Figure 7 is a block diagram of a method for performing a care mode according to the present invention, and Figure 8 is a flowchart of a method for performing a care mode according to the present invention.

When explained with reference to FIGS. 7 and 8, (E) care mode includes the steps of (E1) blocking the supply of raw water and (E2) releasing the pressure formed in the flow path inside the water softener.

This is to prevent moisture from infiltrating the electronic devices and electric circuits inside the water softener due to raw water being supplied or water pressure formed in the flow path inside the water softener during the process of performing the manager's care mode.

Specifically, (E1) the step of blocking the supply of raw water can be achieved by closing the cold water valve 190 located in the cold water inlet 100 and the hot water valve 390 located in the hot water inlet 300. there is.

(E2) The step of releasing the pressure formed in the passage inside the water softener is achieved by opening the cold water rinse valve 890 located in the cold water drain 800 and the hot water rinse valve 990 located in the hot water drain 900. You can.

At this time, in order to release the pressure formed in the passage inside the water softener, the cold water rinse valve 890 and the hot water rinse valve 990 may be opened for a sufficient period of time.

In this regard, the water softener according to the present invention includes a control unit 1100, 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. ) can be formed as a latch valve whose opening and closing is controlled by an electrical signal, and the care mode can be performed by transmitting an electrical signal from the control unit 1100 to the valves 190, 390, 590, and 890.

At this time, the control unit 1100, cold water valve 190, hot water valve 390, regeneration supply valve 590, cold water rinse valve 890, and hot water rinse valve 990 are all batteries provided inside the water softener. It can be configured to operate as a power source.

Accordingly, by forming the water softener so that it is not connected to an external power source, it is possible to prevent problems such as electric leakage and short circuiting related to the electrical connection between the water softener and the external power source when the manager inspects the water softener.

In addition, a battery display unit 1023 is formed on the outer surface of the water softener to display the remaining battery capacity, and the battery display unit 1023 is formed to display a battery replacement alarm when the displayed remaining battery capacity is below a predetermined value. This can increase the administrator's inspection convenience.

Meanwhile, the manager can start performing the (E) care mode by pressing the care button (not shown). When the manager presses the care button, the performance display unit 1021 formed on the outer surface of the lower cover 1020 of the water softener ), a notification indicating that care mode is currently being performed may be displayed.

In addition, when the (E) care mode is performed, the manager can replace the battery provided inside the water softener, which is a consumable item, or the regenerant in the regeneration container.

Preferably, the regenerant in the regeneration tank is configured to regenerate the cold water tank 200 and the hot water tank 400 9 times each, and can be configured to perform a total of 18 regenerations.

The time to perform the regeneration mode of the water softener according to the present invention may be set based on the total flow rate of soft water used by the user, or may be set based on the time from the time the regeneration mode was last performed.

Specifically, when any of the cumulative supply of cold water and soft water measured by the flow sensors 130 and 330 reaches 600L, regeneration of the cold water tank 200 and the hot water tank 400 is performed, and if , Even if the total volume does not reach 600L, if 8 days have passed since the most recent regeneration performance time, the regeneration process is forced to be performed.

In this regard, the (E) care mode is generally performed to fill the rejuvenating agent. In this case, immediately after the (E) care mode is performed, the regenerating container 700 is filled with the regenerating agent, so from this Again, a total of 18 replays can be performed.

Accordingly, when the (E) care mode is performed, the total accumulated flow rate of the flow sensors 130 and 330 and the elapsed time from the time when the last regeneration of the timer 1110 was performed need to be initialized.

The method of performing the care mode according to the present invention is such that when the care button is pressed, the total accumulated flow rate of the flow sensors 130, 330 and the elapsed time from the time when the last playback of the timer 1110 was performed are initialized and stopped. do.

However, when the manager determines that the amount of remaining regenerant is sufficient, the manager can operate the control unit 1100 so that the above-described initialization operation does not proceed.

On the other hand, when the (E) care mode is completed, that is, when the manager completes the maintenance process of the water softener, including replacement of the battery or regenerant provided inside the water softener, the total accumulation of the flow sensors 130, 330 The calculation of flow rate and elapsed time from the time when the last regeneration of the timer 1110 was performed is configured to proceed again from the initialized value.

Above, the present invention has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, but these are merely illustrative examples, and various modifications and equivalent alternatives can be made by those skilled in the art from the embodiments of the present invention. It will be appreciated that embodiments are possible. Therefore, the scope of protection of the present invention should be determined by the scope of the patent claims.

100: Cold water inlet
110: Cold water inlet
120: pressure reducing valve
130: flow sensor
190: cold water valve
200: cold water tank
210: Cold water inlet flow path
220: Filter unit
221: Filter cover
230: Cold water ion exchange resin
240: cold water outlet
300: Hot water intake part
310: Hot water inlet
320: pressure reducing valve
330: flow sensor
390: hot water valve
400: hot water tank
410: Hot water inlet flow path
420: Filter unit
421: Filter cover
430: Hot water ion exchange resin
440: Hot water outlet
500: Play Euro
510: Cold water inlet for regeneration
520: Flow temperature sensor
530: Connector inlet
590: Regenerative supply valve
600: connector
610: Inlet
640: Cold water reclaimed water outlet
645: Check valve
660: Hot water reclaimed water outlet
665: check valve
680: Recycling bin flow path
700: Recycling bin
800: Cold water drain
810: Cold water rinse outlet
820: drain
890: Cold water rinse valve
900: hot water drain
910: Hot water rinse outlet
990: Hot water rinse valve
1010: Top cover
1011: Control panel
1020: Lower cover
1021: Performance display unit
1022: Playing display
1023: Battery indicator
1100: Control unit
1110: Timer

Claims (10)

Cold water intake unit (100);
A cold water tank (200) that receives cold water from the cold water intake unit (100), performs ion exchange, and discharges the water;
Hot water intake unit 300;
A hot water tank (400) that receives hot water from the hot water intake unit (300), exchanges ions, and discharges hot water;
A cold water drain (800) whose one end is connected to the cold water tank (200) and the other end is connected to a drain (820);
a hot water drain (900) with one end connected to the hot water tank (400) and the other end connected to the drain (820);
a first valve including a cold water valve 190 located in the cold water intake unit 100 and a hot water valve 390 located in the hot water intake unit 300;
A regeneration supply valve 590 located in the regeneration flow path 500;
a second valve including 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); and
In a water softener including a control unit 1100 configured to control the operation of the first valve and the second valve, a care mode before a maintenance process of the water softener including replacement of a battery or regenerant provided inside the water softener is performed As a method of performing,
(a) the control unit closes the first valve to block the supply of raw water from the water tap to the cold water tank 200 and the hot water tank 400 (S100); and
(b) the control unit opens the second valve, thereby releasing the pressure formed in the flow path inside the water softener (S200); including,
How to do care mode.
delete According to claim 1,
The water softener,
It further includes a care button;
Before step (a) above,
(a0) pressing the care button (S10); It further includes,
When the care button is pressed, in step (a), the control unit 1100 closes the first valve, and in step (b), the control unit 1100 opens the second valve.
How to do care mode.
According to claim 3,
In step (a0),
When the care button is pressed, the performance display unit 1021 formed on the outer surface of the water softener displays that the care mode is currently being performed.
How to do care mode.
According to claim 3,
The water softener,
Flow sensors 130 and 330 that check the total cumulative flow rate flowing into the cold water tank 200 and the hot water tank 400 in real time, respectively; and
It further includes a timer 1110 that checks in real time the elapsed time from the time when the cold water tank 200 and the hot water tank 400 were last regenerated,
In step (a0), when the care button is pressed,
The total accumulated flow rate of the flow sensors 130, 330 and the elapsed time from the time when the last playback of the timer 1110 was performed are initialized and stopped,
How to do care mode.
According to claim 5,
After step (b) above,
(c) a step (S300) in which a maintenance process of the water softener is performed, including replacement of the battery or regenerant provided inside the water softener,
After step (c), when the care mode is completed and the care mode is released,
Calculation of the total accumulated flow rate of the flow sensors 130, 330 and the elapsed time from the time when the last regeneration of the timer 1110 was performed is performed again from the initialized value,
How to do care mode.
delete According to claim 1,
The cold water valve 190, hot water valve 390, regeneration supply valve 590, cold water rinse valve 890, and hot water rinse valve 990 are all latch valves, and are operated by the control unit 1100. Opening and closing are operated by electrical signals generated,
How to do care mode.
According to claim 8,
The control unit 1100, cold water valve 190, hot water valve 390, regeneration supply valve 590, cold water rinse valve 890, and hot water rinse valve 990 are all powered by a battery provided inside the water softener. Operating as
How to do care mode.
According to clause 9,
A battery display unit 1023 is formed on the outer surface of the water softener to display the remaining amount of the battery,
The battery display unit 1023 displays a battery replacement alarm when the displayed remaining battery capacity is below a predetermined value.
How to do care mode.

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