KR102223012B1 - Separable Regenerator Box of Softener and Drain Basket of the Regenerator Box - Google Patents

Abstract

The present invention is mounted on a water softener, as a regeneration container 700 that contains a built-in regeneration agent, the upper surface 702 formed to be opened so that the regeneration agent can be injected; A seating portion 704 for supporting the rejuvenating agent; And a first port 710 formed to communicate with the regeneration cylinder passage 680 for supplying the regeneration cold water. Including, wherein the seating portion 704 is positioned at a predetermined height from the bottom surface 706 and when the regenerant is seated, the regeneration container is spaced apart by the predetermined height from the bottom surface 706 Provides.

Description

Separable Regenerator Box of Softener and Drain Basket of the Regenerator Box

The present invention relates to a removable recycling bin used in a water softener and a drain basket of the recycling bin.

Tap water (hereinafter referred to as "hard water") contains a large amount of chlorine ions in the purification process, and if it passes through old pipes or if the raw water itself is polluted, iron, zinc, lead, mercury, etc., are harmful to the human body. Various heavy metal ions are included.

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

In order 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+). Soft water from which ions (Ca2+) and magnesium ions (Mg2+) have been removed can be generated. In this way, in order to convert hard water into soft water, a water softener is used in many homes.

In order to exchange calcium ions (Ca2+) and magnesium ions (Mg2+), which are hardness components, with sodium ions (Na+), the water softener is provided with an ion resin tank in which water containing sodium ions (Na+) is stored, and the ions The resin tank consists of a hot water tank and a cold water tank.

At this time, if 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, so sodium in the hot water tank and the cold water tank at regular intervals. It is necessary to replenish ions (Na+).

To this end, the water softener has a regeneration vessel, and after generating regeneration water containing sodium ions (Na+) in the regeneration vessel, sodium ions (Na+) are replenished by supplying the regenerated water to a hot water tank and a cold water tank. .

Specifically, a basket is provided in the regeneration container, and the regeneration agent is embedded in the basket, and the raw water introduced into the regeneration container dissolves the regeneration agent, thereby generating regeneration water.

On the other hand, the prior art, Korean Utility Model No. 20-0363662, relates to a filter for a water softener in which a salt regeneration tank is exchanged, and discloses a structure in which a salt regeneration tank filled with salt is selectively installed.

However, in the process of supplying cold water for regeneration into the regeneration tank that performs regeneration of the water softener, it is inevitably necessary to supply cold water for regeneration into the regeneration tank, and there is a problem that the regeneration cold water overflows in the process of supplying the regeneration cold water. Occurred often.

When the regeneration cold water overflows, a fatal problem occurs that causes failure of an electronic circuit or electronic equipment controlling the water softener.

In addition, it is necessary to separate the regeneration bin for replacement of the regeneration agent that needs to be replaced periodically and cleaning of the regeneration bin, and conventional techniques are not easy to separate the regeneration bin. There may be a problem that residual water penetrates into the water softener.

Accordingly, it is easy to separate and clean the regeneration bin, and when the regeneration cold water supplied in the regeneration bin overflows, there is a need for a technology that prevents the overflowed regeneration cold water from penetrating into the electronic equipment inside the water softener. It is a very high situation.

(Patent Document 1) Korean Utility Model Registration No. 20-0363662

The present invention was devised to solve the above problems.

Specifically, it is proposed to propose a regeneration container having a simple structure in which the process of separating the regeneration container from the water softener is simple by simply forming the combined structure of the regeneration container.

In addition, when the regeneration cold water supplied to the regeneration tank overflows, it is intended to propose a structure that prevents the regeneration cold water from penetrating into electronic equipment and electric circuits inside the water softener.

One embodiment of the present invention for solving the above problems is a regeneration container 700 mounted on a water softener and containing a regenerating agent 730, which is open and formed so that the rejuvenating agent 730 can be injected. Upper side; Mounting portions 704a and 704b for supporting the regenerant 730; And a first port 710 formed to communicate with the regeneration cylinder passage 680 for supplying the regeneration cold water. Including, the seating portion (704a, 704b) is positioned at a predetermined height from the bottom surface 706, when the rejuvenating agent 730 is seated, the predetermined height from the bottom surface 706 Provides a regeneration bin, spaced apart by as much as possible.

In addition, the rejuvenating agent 730 is inserted into the regenerating container 700 while being inserted into the regenerating agent basket 720, so that the regenerating agent basket 720 is supported by the seating portions 704a and 704b. It is preferable that a predetermined portion of the regenerant basket 720 is formed of a mesh so that the regenerating cold water dissolves the regenerant inserted into the regenerant basket 720.

In addition, the first port 710 is formed on the bottom surface 706, and the regeneration water in which the regenerant 730 is dissolved by the regeneration cold water is regenerated through the first port 710. It is preferably formed to be discharged to the outside of the barrel 700.

In addition, it is preferable that a gradient is formed on the bottom surface 706 toward the first port 710.

Further, the drain wall 708 is spaced apart from the inner surface of the regeneration container 700 by a predetermined distance to form a drainage space 707; And a second port (709) formed on the bottom surface of the drainage space (707). It further includes, and when the cold water for regeneration overflows, it is preferable that it is formed to be discharged to the outside of the regeneration container 700 through the second port 709.

In addition, the regenerant basket 720 is formed to correspond to the size of the regenerant 730, and the drain wall 708 has an upper end 708a of the upper end 720a of the regenerant basket 720 It is preferably formed to a height corresponding to.

On the other hand, an embodiment of the present invention, the above-described regeneration canister 700; And a regeneration bin drain basket 750 disposed below the regeneration bin 700 and formed to temporarily store the regeneration cold water discharged to the outside of the regeneration bin 700 through the second port 709. ; Containing, it provides a water softener.

In addition, a third port 754 formed to discharge cold water for regeneration temporarily stored therein to the outside is formed on the bottom surface 752 of the regeneration bin drain basket 750, and the third port ( It is preferable that 754 is located in a straight line in a direction perpendicular to the second port 709.

In addition, it is preferable that a gradient is formed toward the third port 754 on the bottom surface 752 of the regeneration bin drain basket 750.

In addition, in the regeneration bin drain basket 750, a hollow first port receiving portion 756 protruding toward the first port 710 is formed, and one side of the first port receiving portion 756 is , By being inserted in close contact with the first port 710, the recycling bin 700 and the recycling bin drain basket 750 are coupled and fixed, and the other side of the first port receiving part 756 is for the recycling. It is preferable to communicate with the regeneration cylinder passage 680 for supplying cold water.

In addition, on the outer circumferential surface of the first port 710, a protrusion 712 formed of an elastic member is formed so that the first port 710 is in close contact with the inner circumferential surface of the first port receiving part 756, 1 The inner circumferential surface of the port receiving portion 756 is formed to have a predetermined inclination, the diameter of the inner circumferential surface decreases toward the insertion direction of the first port 710, and the protrusion of the first port 710 ( At least one 712 is formed in a closed shape along the circumferential direction of the outer circumferential surface of the first port 710, and the degree of protrusion of the plurality of protrusions 712 is in the insertion direction of the first port 710 It is preferable that it is formed so as to decrease gradually.

In addition, the water softener, the regeneration passage 500 in communication with the cold water receiving unit 100; And a connector for receiving cold water for regeneration from the regeneration passage 500 and supplying it to the regeneration vessel 700, and receiving regeneration water from the regeneration vessel 700 and transferring the regeneration water to the cold water tank 200 or the hot water tank 400 ( 600); Including, the connector 600, the inlet passage 610 in communication with the regeneration passage 500; A recycling bin flow path 680 whose one end is communicated with the recycling bin 700; A cold water regeneration water outlet passage 640 branched from the other end of the regeneration tank passage 680 and communicated with the cold water tank 200; And a hot water regeneration water outlet passage 660 branched from the other end of the regeneration vessel passage 680 and communicated with the hot water tank 400, wherein the regeneration cold water supplied through the regeneration vessel passage 680 is , Is supplied to the regeneration container 700 through the first port receiving portion 756 and the first port 710, and the regeneration water is supplied to the first port 710 and the first port receiving unit 756 ) Is preferably supplied to the cold water tank 200 and the hot water tank 400.

In the present invention, by forming an inlet passage for supplying cold water for regeneration to the regeneration vessel and an outlet passage for supplying regeneration water to the outside with the same first port, the structure of the regeneration vessel was simply formed, and the first port was formed. Through this, by forming a structure in which the regeneration container is mounted inside the water softener, the ease of separation of the regeneration container is increased.

In addition, the present invention prevents the regeneration cold water from penetrating into electronic circuits and electronic equipment inside the water softener by providing a regeneration bin drain basket capable of temporarily storing it when the regeneration cold water overflows.

In addition, by forming a gradient and a separate drainage space in the regeneration container, the regeneration water is prevented from remaining in the regeneration container, and the phenomenon that the cold water for regeneration overflows in the regeneration container is prevented.

1 is a perspective view showing the appearance of a water softener according to the present invention.
2 and 3 are perspective views illustrating the water softener according to the present invention in which the upper cover and the lower cover are removed for explanation, and the frame and some connecting parts are omitted. As can be seen from the coordinate system, FIG. 2 is It is a perspective view as viewed from the front lower side, and FIG. 3 is a perspective view as viewed from the rear upper side.
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.
5B is a view schematically showing a flow path (steps C11 and C21 below) through which cold water for regeneration is supplied in the water softener according to the present invention.
5C is a diagram schematically illustrating a flow path (step C13 below) for supplying regenerated water to a cold water tank in the water softener according to the present invention.
5D is a diagram schematically illustrating a flow path (step C24 below) for supplying regenerated water to a hot water tank in the water softener according to the present invention.
6 is a view for explaining the operation mode of the water softener according to the present invention and the operation of the valve according to the present invention.
7 is a perspective view showing a regeneration container of the water softener according to the present invention.
8 is a plan view of the regeneration container shown in FIG. 7.
9 is a front view of the regeneration container shown in FIG. 7.
10 is a perspective view showing a lower portion of the regeneration container shown in FIG. 7.
FIG. 11 is a front view showing a state in which a regeneration bin drain basket is coupled to a lower portion of the regeneration bin shown in FIG. 7.
12 is a perspective view showing a lower portion of the regeneration bin and the regeneration bin drain basket shown in FIG. 11 in a combined state.
13 is a perspective view of a regeneration bin drain basket according to the present invention.
14 is a cross-sectional view taken along line A-A' of FIG. 8.
15 is an enlarged view of area B shown in FIG. 11.

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.

"Regenerated water" means a fluid for supplying ions to an ion exchange resin by melting a regeneration block, which may be salt, for example. When "regeneration water" is supplied to the cold water tank, it is referred to as "cold water regeneration water", and when it is supplied to the hot water tank, it is referred to as "hot water regeneration water".

"Cold water for regeneration" means cold water supplied to produce 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 is an appearance of a water softener according to the present invention, and an upper cover 1010 and a lower cover 1020 are shown. For explanation, the upper cover 1010 is shown transparently.

The regeneration tank 700 is located at 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 below the regeneration tank 700. The upper cover 1010 is removed to replace the filter or fill the regeneration container 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 displaying the number of times of playback, and an input unit for inputting a current time setting, a playback setting, a care mode, a manual playback, and the like.

The lower cover 1020 protects the inner flow path.

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

2 to 3 show the water softener from which the upper cover 1010 and the lower cover 1020 are removed. For the sake of explanation, illustration of the frame and the connecting parts for fixing the respective parts to the frame has been omitted.

4 shows the connector 600, and FIGS. 5A to 5D schematically show a flow path. In FIGS. 2 to 3, the illustration of a tube to which each component is connected is omitted, which will be described below and a connection method thereof can be confirmed 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 together.

1.1 Cold water intake part (100)

The water softener according to the present invention, a cold water intake unit 100, a cold water tank 200, a hot water intake unit 300, a hot water tank 400, a regeneration flow path 500, a connector 600, a regeneration container 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 faucet (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 faucet to receive cold water. The supplied cold water passes through the pressure reducing valve 120 and is depressurized, and the flow rate of the cold water supplied by the flow sensor 130 is checked.

The cold water valve 190 is provided between the cold water inlet 110 and the cold water inlet flow path 210 and controls whether or not cold water is introduced. The cold water valve 190 is controlled according to the operation mode, which will be described later in detail.

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 for water to be discharged, or to supply the cold water to the regeneration tank 700 as cold water for regeneration. It includes a cold water intake passage 210, a filter unit 220, a cold water ion exchange resin 230, and a cold water outlet 240.

The cold water intake passage 210 is connected to the cold water intake unit 110, is provided in the middle of the cold water tank 200 as shown in FIGS. 2 and 3, and is filled in a manner that the cold water ion exchange resin 230 surrounds it. Can be. The cold water introduced through the cold water intake passage 210 rises.

A filter unit 220 is positioned at an end of the cold water intake channel 210, and the cold water supplied through the cold water intake channel 210 is filtered by the filter unit 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 regeneration cold water through a regeneration cold water inlet 510, which is a tube (see FIGS. 5A to 5D). Some of them flow to the cold water regeneration water outlet passage 640 including other tubes, but do not flow to the connector 600 by the check valve 645, but only the hydraulic pressure in the passage is maintained.

After passing through the filter unit 220 and flowing radially outward, the cold water descending while passing through the cold water ion exchange resin 230 is softened by an ion exchange action. The softened cold water is discharged to the user through the cold water outlet 240.

1.3 Hot water intake part (300)

The hot water receiving unit 300 is located at the bottom of the water softener and is connected to a hot water faucet (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 receiving port to receive hot water, and the supplied hot water passes through the pressure reducing valve 320 and is depressurized, and the flow rate of the hot water supplied by the flow sensor 330 is checked.

The hot water valve 390 is provided between the hot water inlet 310 and the hot water inlet flow path 410 and controls whether or not 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 to discharge water. Unlike the cold water tank 200, hot water is not supplied to the regeneration tank 700. It includes a hot water intake passage 410, a filter part 420, a hot water ion exchange resin part 430, and a hot water outlet 440.

The hot water intake passage 410 is connected to the hot water intake unit 310, is provided in the middle of the hot water tank 400 as shown in FIGS. 2 and 3, and is filled in a manner that the hot water ion exchange resin 430 surrounds it. Can be. The hot water introduced through the hot water intake passage 410 rises.

A filter unit 420 is positioned at an end of the hot water intake passage 410, and the hot water supplied through the hot water intake passage 410 is filtered by 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 passing 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 flow path 500. Some of them flow to the hot water regeneration water outlet passage 660 including a tube, but they do not flow to the connector 600 by the check valve 665, but only the hydraulic pressure in the passage is maintained.

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

1.5 Regeneration Euro (500)

The regeneration passage 500 serves to supply the cold water supplied through the cold water receiving unit 100 and the cold water tank 200 to the regeneration container 700 through the connector 600 as regeneration cold water to generate regeneration water. It includes a regeneration cold water intake 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 intake 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 intake passage 510. The regenerative supply valve 590 is controlled according to the operation mode, which will be described later in detail. The flow rate and temperature of the regeneration cold water sensed by the flow rate temperature sensor 520 may be used for determining the number of times of regeneration and determining the regeneration time.

1.6 connector (600)

The connector 600 supplies the regeneration cold water supplied from the regeneration passage 500 to the regeneration vessel 700, and transfers the regeneration water generated in the regeneration vessel 700 to the cold water tank 200 and the hot water tank 400. Plays a role. The inlet passage 610, the cold water regeneration water outlet passage 640 and the check valve 645 provided therein, the hot water regeneration water outlet passage 660 and the check valve 665 provided therein, and the regeneration vessel 700 It includes a recycle bin flow path 680.

The inlet passage 610 is connected to the connector inlet passage 530, through which cold water for regeneration is received in the regeneration vessel 700.

The regeneration tank 700 is connected to one end of the cold water regeneration water outlet passage 640 and the other end is connected to the cold water tank 200. Normally, the flow path from the check valve 645 to the cold water tank 200 of the cold water regeneration water outlet passage 640 is filled with cold water to maintain a constant hydraulic pressure. As described above, cold water is not delivered to the regeneration bin 700 due to the check valve 645. During regeneration, cold water regenerated water from the regeneration tank 700 is supplied to the cold water tank 200 through the cold water regeneration water outlet passage 640.

Likewise, the regeneration tank 700 is connected to one end of the hot water regeneration water outlet passage 660 and the other end is connected to the hot water tank 400. Normally, hot water is filled in the flow path from the check valve 665 to the hot water tank 400 among the hot water regeneration water outlet passage 660 to maintain a constant hydraulic pressure, and the hot water is delivered to the regeneration tank 700 due to the check valve 665 It doesn't work. During regeneration, the hot water regenerated water from the regeneration tank 700 is supplied to the hot water tank 400 through the hot water regeneration water outlet channel 660.

Normally (that is, (B) soft water mode, which will be described later), the cold water passes through the filter unit 220 and is filled up to the check valve 645 of the cold water regeneration water outlet passage 640, and the hot water passes through the filter unit 420 to provide hot water. The regeneration water outlet passage 660 is filled up to the check valve 665. In the water softener according to the present invention, the cold water tank 200 and the hot water tank 400 are structured to communicate through the cold water regeneration water outlet passage 640 and the hot water regeneration water outlet passage 660. Because of this, mixing is usually prevented. As will be described later, due to the check valves 645 and 665, the regenerated water generated in one regeneration tank 700 can be supplied to both the cold water tank 200 and the hot water tank 400.

One end of the regeneration canister flow path 680 is connected to the regeneration canister 700, and the other end is connected to all of the three flow paths, namely, the inlet path 610, the cold water regeneration water outlet 640, and the hot water regeneration water outlet 660. . In the case of supplying the regeneration cold water, the regeneration cold water passes through the inlet passage 610 and the regeneration cylinder passage 680, and in the drawing, the regeneration cold water flows upward in the regeneration vessel passage 680. On the other hand, the cold water regenerated water passes through the regeneration canister passage 680 and the cold water regeneration water outlet passage 640, and the hot water regeneration water passes through the regeneration tub passage 680 and the hot water regeneration water outlet passage 660, and in the drawing, the regeneration tub passage 680 ) Flows downwards.

1.7 Recycle Bin (700)

The regeneration container 700 receives cold water for regeneration from the connector 600 and generates regeneration water.

The regeneration container 700 may be filled with a regeneration block (not shown). When the cold water for regeneration passes through the cold water inlet 110, the cold water inlet passage 210, the filter unit 220, the regeneration cold water inlet passage 510, and the inlet passage 610 and is supplied to the regeneration tank 700, it is regenerated. As the dragon block (not shown) melts, it generates regeneration water.

Here, the regenerated cold water and the regenerated hot water are the same regenerated water generated in the regeneration tank 700 and are classified according to whether they are supplied to either the cold water tank 200 or the hot water tank 400. That is, some of the regenerated water generated in the regeneration tank 700 is supplied to the cold water tank 200 through the cold water regeneration water outlet passage 640 of the connector 600, and the regeneration water supplied at this time is cold water regeneration water, and the other part is the connector. The hot water regeneration water outlet passage 660 of 600 is supplied to the hot water tank 400, and the regeneration water supplied at this time is hot water regeneration water. In general, regenerated cold water is first supplied to the cold water tank 200 and then regenerated hot water is supplied to the hot water tank 400.

When cold water regenerated 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 regenerated water flows into the hot water tank 400, it is supplied to the hot water ion exchange resin 430, and ions in the hot water ion exchange resin 430 are regenerated.

In addition, the lower end of the regeneration vessel 700 may be connected by a drain 820 and a tube so that regeneration water or rinsed water overflowing from the regeneration vessel 700 is discharged through a drain 820 to be described later. have.

Meanwhile, a detailed structure of the regeneration bin 700 and the regeneration bin drain basket 750 will be described below with reference to FIGS. 7 to 15.

1.7-1 Detailed structure of the recycling bin 700

7 to 10 show the structure of the regeneration container 700.

The upper surface of the regeneration container 700 is formed to be open so that the regeneration agent 730 can be injected.

Preferably, the regeneration bin 700 is formed to accommodate 1.5L of cold water for regeneration, and based on this, the regenerant 730 is formed such that a 3.1kg regeneration agent block is injected.

On the other hand, when the regeneration agent 730 is seated in the regeneration container 700, in order to form it so that it does not contact the bottom surface of the regeneration container 700, the seating portions 704a and 704b for supporting the regeneration agent 730 It is equipped with.

This is to prevent the phenomenon that the remaining regenerated water continuously dissolves the regenerator 730 when regeneration water remains in the regeneration tank after the regeneration is completed, and ultimately, a certain salinity of the regenerated water is secured and the regeneration agent It is to secure a certain period of use of (730).

The seating portions 704a and 704b are formed to have a height of 25 mm from the bottom surface, and the bottom surface 706 is preferably formed with a 3.5 degree gradient in order to prevent the remaining of the regenerated water.

On the bottom surface 706 of the regeneration tub 700, a first port 710 is formed to communicate with the regeneration tub passage 680 for supplying cold water for regeneration, and the regeneration water is also the first port 710. It is formed to be discharged through, and the gradient formed on the bottom surface 706 of the regeneration container 700 is formed toward the first port 710.

On the other hand, the regenerating agent 730 is inserted into the regeneration container 700 while being inserted into the regenerating agent basket 720, and the regenerating agent basket 720 is supported and fixed by the seating portions 704a and 704b.

At this time, a predetermined portion of the regenerant basket 720 is formed of a mesh so that cold water for regeneration dissolves the regenerant inserted into the regenerant basket 720.

In this way, instead of directly administering the regenerating agent 730 to the regeneration container 700, the regenerating agent 730 is administered to the regenerating agent basket 720, and then the regenerating agent basket 720 is placed in the regeneration container 700. Install it inside.

Accordingly, in the process of dissolving the regenerating agent 730, the pieces of the regenerating agent 730 are separated to prevent the pieces of the regenerating agent 730 from touching the bottom surface of the regeneration container 700, as described above. , This is to ensure a constant salinity of regenerated water.

On the other hand, on the inner surface of the regeneration container 700, a drain wall 708 that is spaced apart from the inner surface by a predetermined distance to form a drain space 707 and a second port formed on the bottom surface of the drain space 707 (709); It further includes.

This is for discharging the regeneration cold water to the outside of the regeneration container 700 through the second port 709 when the regeneration cold water overflows, and specifically, the level of the supplied regeneration cold water is the drainage wall. This is to prevent formation of the regeneration water higher than the height of 708, and the water level of the supplied regeneration cold water is formed higher than the drainage wall 708 to prevent the phenomenon that the regeneration cold water overflows the regeneration container.

In addition, when the regeneration water is generated, the regeneration cold water is supplied so that the regeneration agent 730 is completely immersed in the regeneration cold water, and the drain wall 708 has an upper end portion 708a of the upper end portion 720a of the regeneration agent basket 720. It is preferably formed to a height corresponding to.

In FIG. 14, a state in which the regenerating agent 730 is embedded in the regenerating agent basket 720 and fixed inside the regenerating container 700 is shown.

At this time, the seating portions 704a and 704b in the regeneration container 700 may have different heights, and when the heights are different, the regenerant basket 720 to maintain the level of the regeneration agent basket 720 Ribs may be formed on the lower surface of the.

In addition, by forming a handle on the upper surface of the regenerant basket 720 to facilitate replacement of the regenerant 730, the lid of the regenerant basket 720 may be easily opened and closed.

1.7-2 Detailed structure of the recycling bin drain basket (750)

13 shows a detailed structure of the regeneration bin drain basket 750.

The regeneration bin drain basket 750 is located under the regeneration bin 700 and is formed to temporarily store the regeneration cold water discharged to the outside of the regeneration bin 700 through the above-described second port 709 do.

That is, when the regeneration cold water supplied to the regeneration canister 700 overflows, the overflowed regeneration cold water is stored in the regeneration canister drain basket 750 along the drainage space 707 of the regeneration tub 700. It will be.

At this time, a third port 754 for discharging the regeneration cold water temporarily stored therein to the outside is also formed on the bottom surface of the regeneration bin drain basket 750, and preferably, the regeneration bin 700 The second port 709 and the third port 754 of the regeneration bin drain basket 750 are positioned on a straight line in the vertical direction, so that it is possible to facilitate the discharge of overflowed regeneration cold water.

In addition, the regeneration bin drain basket 750 may also have a gradient toward the third port 754.

On the other hand, the height of the inner wall of the regeneration bin drain basket 750 is the lower surface of the regeneration bin 700 to prevent splashing of the overflowed regeneration cold water flowing from the second port 709 of the regeneration bin 700 It can be formed to be close to.

In the regeneration bin drain basket 750 according to an embodiment of the present invention, a hollow first port receiving portion 756 protruding toward the first port 710 is formed, and the first port receiving portion 756 The upper side of) is formed so that the first port 710 is inserted in close contact, and the lower side is formed to communicate with the regeneration cylinder flow path 680.

In this way, a flow path for receiving cold water for regeneration and supplying regeneration water is unified into the first port 710, and the first port 710 of the regeneration canister 700 and the first port of the regeneration canister drain basket 750 Through the coupling of the receiving portion 756, the regeneration tank 700 and the regeneration tank drain basket 750 may be physically connected while connecting the flow path through which the regeneration cold water and the regeneration water flow.

As shown in FIG. 15, a protrusion 712 formed of an elastic member is formed on the outer circumferential surface of the first port 710 so that the first port 710 and the first port receiving portion 756 are more closely contacted. I can.

In addition, the inner circumferential surface of the first port receiving portion 756 may be formed to have a predetermined inclination, and may be formed such that the diameter of the inner circumferential surface decreases toward the insertion direction of the first port 710.

Accordingly, the first port 710 of the recycling bin 700 can be easily inserted into the first port receiving portion 756 of the drain basket 750 of the recycling bin.

In addition, a plurality of protrusions 712 of the first port 710 may be formed in a closed shape along the circumferential direction of the outer circumferential surface of the first port 710, preferably formed to have a triple sealing structure. I can.

At this time, the protrusion degree of the plurality of protrusions 712 is formed to decrease toward the insertion direction of the first port 710, so that it may correspond to the inclination formed on the inner circumferential surface of the first port receiving part 756 described above. Accordingly, it is possible to increase the ease of insertion and sealing of the first port 710 into the first port receiving portion 756.

1.8 Cold water drain (800)

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

One end of the cold water rinse outlet passage 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 water rinsed in the hot water tank 400 through the drain 820. It includes a hot water rinse outlet passage 910 and a hot water rinse valve 990.

Similarly, one end of the hot water rinse outlet passage 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. Description of the operation mode of the water softener

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

The operation 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 bottle rinse mode.

Each mode can be implemented through the 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 use a single multi-way valve including a ceramic disk, but due to the nature of the water softener operating in a humid environment, there are many cases of malfunction, leading to leakage or failure. The operation mode was implemented by dividing the two valves.

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 preferably latch valves, but other types of electronically controllable Of course, a valve is also possible.

(A) The raw water mode is an operation mode when the user uses raw water rather than soft water, and a detailed description thereof will be omitted.

2.1 Training mode

(B) training mode is when the user uses soft water, 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, and the hot water rinse valve 990 It is implemented by closing it.

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 passes through the filter unit 220 and does not flow to the regeneration flow path 500, but cold water ions It is softened by passing through the exchange resin 230.

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

The same is true for hot water.

2.2 Playback mode

(C) In the regeneration mode, when ions in 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 are reduced and it is difficult to generate soft water, regeneration water is supplied to each of the This is a mode to regenerate resin. After regeneration cold water is supplied to the regeneration tank 700 to generate regeneration water, the regeneration 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 start time of the regeneration mode may be set based on the total flow rate of the number of years used by the user, and/or may be set based on the time from the time when the last regeneration mode is performed.

For example, if the user uses cold water or hot water softened by exceeding the reference flow rate of a total of 600 liters, (C) the regeneration mode may be performed. The amount of soft water used can be checked 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 reference flow rate, it is preferable to regenerate both the cold water tank 200 and the hot water tank 400. This is to prevent the regeneration mode (C) that the user cannot use the water softener too often because it takes about 1 hour, and to manage the ion exchange resin on the cold and hot water side in an integrated manner.

At the same time, if 8 days have elapsed from the time when the last regeneration mode was performed, even if the flow rate used by the user does not exceed the reference flow rate, (C) the regeneration mode can be performed. This is to be prepared in case of a failure of the flow meter or when the function of the ion exchange resin naturally decreases over time.

The (C) regeneration mode will be described by dividing into (C1) cold water tank regeneration mode and (C2) hot water tank regeneration mode.

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

(C11) The supply of cold water for regeneration is generally started by changing from the (B) training mode, which is normally operated. To this end, the regeneration supply valve in the (B) training mode in which 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, and the hot water rinse valve 990 are closed. Only (590) is open. Now, the cold water supplied through the cold water inlet 110 passes through the filter unit 220 and then flows toward the regeneration cold water inlet 510 due to the opening of the regeneration supply valve 590, and the connector inlet 530 ), it is supplied to the recycling bin 700 through the intake path 610 and the recycling bin flow path 680. The amount of cold water for regeneration supplied to the regeneration tank 700 is checked by the flow rate temperature sensor 520.

When the amount of cold water for regeneration checked by the flow temperature sensor 520 reaches a predetermined amount (ie, the capacity of the regeneration container 700), the process proceeds to the dissolution step (C12). It starts by closing the regeneration supply valve 590 that was open. Since both the regeneration supply valve 590 and the cold water rinse valve 890 are closed to maintain pressure, the regeneration water generated in the regeneration tank 700 does not flow into the cold water tank 200 and has a dissolution 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 and flow rate of the cold water for regeneration.

When all the dissolution time has elapsed, it proceeds to the (C13) regeneration step. It starts by closing the cold water valve 190 that has been opened, and opening the cold water rinse valve 890 that has been closed. Due to the opening of the cold water rinse valve 890, the pressure on the side of the cold water tank 200 is lowered, and the regeneration water (that is, cold water regeneration water) passes through the regeneration cylinder passage 680, the cold water regeneration water outlet passage 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 regenerated water regenerates the cold water ion exchange resin 230, passes through the cold water rinse outlet passage 810, and is discharged to the outside through the drain 820. It is preferred to take place during a regeneration time of about 20 minutes, but the time is variable.

When the regeneration time has elapsed, proceed to the rinse step (C14). It starts by opening the cold water valve 190 that was closed. Cold water is received from the cold water inlet 110, and it is rinsed by entering the cold water ion exchange resin 230 through the filter unit 220. Thereafter, the opened cold water rinse valve 890 passes through the cold water rinse outlet passage 810 and is discharged to the outside through the drain 820. It is preferable to take about 3 minutes, but the time can be varied.

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

(C21) The supply of cold water for regeneration is generally performed after the (C14) rinsing step. In the rinsing step (C14) in which the cold water valve 190, the hot water valve 290, and the cold water rinse valve 890 are open and the regeneration supply valve 590 and the hot water rinsing valve 990 are closed, the regeneration supply valve It begins by opening 590 and closing the 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 determined by the flow temperature sensor 520 reaches a predetermined amount, the process proceeds to the dissolution step (C22). It starts by closing the regeneration supply valve 590 that has been opened, and has a dissolution time in which the regeneration block (not shown) is melted. Similarly, the dissolution time may be determined differently depending on the temperature and flow rate of cold water for regeneration.

When all the dissolution time has elapsed, it proceeds to the step of removing hot water air (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 regeneration flow path 500, whereas the hot water tank 400 does not have such a flow path, so it is effective to remove air and supply the regeneration water. to be. For this, the hot water rinse valve 990 is opened for about 10 seconds. In this case, the hot water tank 400 and air on the related flow path are discharged to the outside through the drain 820.

On the other hand, since (C23) dissolution can continue in the regeneration tank 700 even during the hot water air removal step, it is preferable to consider the time of the (C23) hot water air removal step as the time at which the (C22) dissolution step is performed. In other words, the (C23) hot water air removal step is performed at the same time as 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 the dissolution time in the (C22) dissolution step remains 10 seconds.

Now, it proceeds to the (C24) playback step. It starts by closing the hot water valve 390 that has been opened, and opening the hot water rinse valve 990 that has been closed. (C13) In the same manner as in the regeneration step, the hot water regenerated water is supplied to the hot water ion exchange resin 430 through the regeneration tank passage 680, the hot water regeneration water outlet passage 665, and the filter unit 420, so that the hot water ion exchange resin 430 ), and then passed through the hot water rinse outlet passage 910 and discharged to the outside through the drain 820. It is preferred to take place during a regeneration time of about 20 minutes, but the time is variable.

When the regeneration time has elapsed, proceed to the rinse step (C25). It starts by opening the hot water valve 390 which was closed. (C14) In the same manner as in the rinsing step, hot water is received from the hot water inlet 310, and it is rinsed by entering the hot water ion exchange resin 430 through the filter unit 420. Thereafter, the hot water rinse valve 990 passes through the hot water rinse outlet passage 910 and is discharged to the outside through the drain 820. It is preferable to take about 3 minutes, but the time can be varied.

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

2.3 Regeneration bottle rinse mode

(D) The regeneration container rinse mode is the (D1) cold water supply step for rinsing. (D2) a regeneration container drain step, (D3) cold water rinsing step, and (D4) hot water rinsing step.

(D1) In the step of supplying cold water for rinsing, cold water is supplied for cleaning the regeneration container 700 while all of the regeneration 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, 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 hot water rinse valve 990 that has been opened is closed, and the regeneration supply valve 590 that has been closed is opened. Accordingly, the cold water supplied through the cold water inlet 110 passes through the filter unit 220 and then flows toward the regeneration cold water intake passage 510 due to the opening of the regeneration supply valve 590, and the connector inlet passage It is supplied to the recycling bin 700 by passing through the 530 and the inlet 610. The flow rate supplied at this time is sufficient to fill only a part of the regeneration container 700. For example, if 1.5 liters are supplied in steps (C11) to (C12), only 0.5 liters can be supplied in steps (D11).

Next, the (D12) regeneration tank drain step is performed. The opened 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 water remaining in the regeneration container 700.

Next, (D13) cold water rinsing step is performed. As a step of rinsing the cold water tank 200, the closed cold water valve 190 is opened to introduce cold water into the cold water tank 200, and then rinsed to drain.

Next, (D14) hot water rinsing step is performed. As a step of rinsing the hot water tank 400, the closed hot water valve 390 is opened to introduce hot water into the hot water tank 400, followed by rinsing and draining.

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

Now, (B) return to 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 training mode (B).

As described above, in the present specification, 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 this is only illustrative, and those skilled in the art It will be appreciated that examples are possible. Therefore, the scope of protection of the present invention should be determined by the claims.

100: cold water intake part
110: cold water intake
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: Intake of cold water for regeneration
520: flow temperature sensor
530: connector inlet
590: regenerative supply valve
600: connector
610: inlet
640: cold water regeneration water outlet
645: check valve
660: hot water regeneration water outlet
665: check valve
680: Recycled barrel euro
700: recycle bin
710: first port
720: basket for regenerant
750: recycle bin drain basket
756: first port receiving portion
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
1022: display during playback
1023: battery display

Claims (12)

As a regeneration container 700 mounted on the water softener and containing a regeneration agent 730,
An upper surface formed to be open so that the regenerant 730 can be injected;
Mounting portions 704a and 704b for supporting the regenerant 730;
A first port 710 formed to communicate with the regeneration cylinder passage 680 for supplying cold water for regeneration;
A drain wall 708 that is spaced apart from the inner surface of the regeneration container 700 by a predetermined distance to form a drainage space 707; And
A second port 709 formed on the bottom surface of the drainage space 707; Including,
The seating portions 704a and 704b are positioned at a predetermined height from the bottom surface 706 and are spaced apart from the bottom surface 706 by the predetermined height when the regenerant 730 is seated,
Formed to be discharged to the outside of the regeneration container 700 through the second port 709 when the regeneration cold water overflows,
Recycle bin.
The method of claim 1,
The regenerant 730 is inserted into the regeneration container 700 while being inserted into the regenerant basket 720, and the regenerant basket 720 is supported by the seating portions 704a and 704b,
A predetermined portion of the regenerating agent basket 720 is formed of a mesh so that the regeneration cold water dissolves the regenerating agent inserted into the regenerating agent basket 720,
Recycle bin.
The method of claim 1,
The first port 710 is formed on the bottom surface 706,
The regeneration water in which the regeneration agent 730 is dissolved by the regeneration cold water is formed to be discharged to the outside of the regeneration container 700 through the first port 710,
Recycle bin.
The method of claim 3,
The bottom surface 706 has a gradient toward the first port 710,
Recycle bin.
delete The method of claim 1,
The rejuvenating agent basket 720 into which the rejuvenating agent 730 is inserted is formed to correspond to the size of the rejuvenating agent 730,
The drainage wall 708 has an upper end 708a formed at a height corresponding to the upper end 720a of the regenerant basket 720,
Recycle bin.
Recycling bin 700 according to claim 1; And
A regeneration bin drain basket 750 positioned below the regeneration bin 700 and formed to temporarily store the regeneration cold water discharged to the outside of the regeneration bin 700 through the second port 709; Containing,
Water softener.
The method of claim 7,
A third port 754 formed to discharge cold water for regeneration temporarily stored therein to the outside is formed on the bottom surface 752 of the regeneration bin drain basket 750,
The third port 754 is located on a straight line in a vertical direction with the second port 709,
Water softener.
The method of claim 8,
On the bottom surface 752 of the regeneration bin drain basket 750, a gradient is formed toward the third port 754,
Water softener.
The method of claim 7,
In the regeneration bin drain basket 750, a hollow first port receiving portion 756 protruding toward the first port 710 is formed,
One side of the first port receiving portion 756 is inserted in close contact with the first port 710, so that the recycling bin 700 and the recycling bin drain basket 750 are coupled and fixed,
The other side of the first port accommodating portion 756 is in communication with a regeneration cylinder passage 680 for supplying the regeneration cold water,
Water softener.
The method of claim 10,
On the outer circumferential surface of the first port 710,
A protrusion 712 formed of an elastic member is formed so that the first port 710 is in close contact with the inner circumferential surface of the first port receiving part 756,
The inner circumferential surface of the first port receiving portion 756 is formed to have a predetermined inclination, and the diameter of the inner circumferential surface decreases toward the insertion direction of the first port 710,
At least one protrusion 712 of the first port 710 is formed in a closed shape along the circumferential direction of the outer circumferential surface of the first port 710, and the degree of protrusion of the plurality of protrusions 712 is, Formed to decrease gradually in the insertion direction of the first port 710,
Water softener.
The method of claim 10,
The water softener,
Regeneration passage 500 in communication with the cold water receiving unit 100; And
A connector 600 that receives cold water for regeneration from the regeneration passage 500 and supplies it to the regeneration vessel 700, and receives regeneration water from the regeneration vessel 700 and delivers it to the cold water tank 200 or the hot water tank 400. ); Including,
The connector 600,
An inlet passage 610 connected to the regeneration passage 500;
A recycling bin flow path 680 whose one end is communicated with the recycling bin 700;
A cold water regeneration water outlet passage 640 branched from the other end of the regeneration tank passage 680 and communicated with the cold water tank 200; And
And a hot water regeneration water outlet passage 660 branched from the other end of the regeneration tank passage 680 and communicated with the hot water tank 400,
The cold water for regeneration supplied through the regeneration vessel passage 680 is supplied to the regeneration vessel 700 through the first port receiving portion 756 and the first port 710,
The regeneration water is supplied to the cold water tank 200 and the hot water tank 400 through the first port 710 and the first port receiving part 756,
Water softener.

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