KR20140113161A - Water Softener System with single inlet/outlet of recovery tank - Google Patents

Abstract

The present invention relates to a water softener system including: an ion exchange resin filter that converts raw water, supplied through a raw water supply passage, into soft water through an ion exchange resin filling the ion exchange resin filter; a regenerating tank, which stores a regenerant for regenerating the ion exchange resin and supplies raw water introduced through the raw water supply passage to the ion exchange resin filter to regenerate the ion exchange resin filter; and a passage turning part installed between the regenerating tank and the ion exchange resin filter to change the direction of a passage between the regenerating tank and the ion exchange resin filter. A passage is formed around the regenerating tank such that raw water can be introduced and discharged through only a single outlet formed on the regenerating tank. Accordingly, the passage is simplified to improve space occupation efficiency, thereby saving manufacturing costs.

Description

[0001] Water softener system with single inlet / outlet of recovery tank [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water softener system, and more particularly, to a water softener system that can simplify a flow path around a regenerator to increase space utilization and thereby reduce manufacturing cost.

In general, a water softener is a device that reacts raw water such as tap water or ground water with an ion exchange resin to remove hardness-inducing substances such as calcium and magnesium ions, thereby making raw water into soft water such as hot spring water.

Such a water softener usually has an ion exchange resin filter filled in a column and a column provided with an inlet and an outlet, and raw water is introduced from the inlet channel of the column, and the introduced raw water flows into the column The hardness components such as calcium ions and magnesium ions are ion-exchanged with the chemical functional groups of the ion exchange resin filter through the exchange resin filter to be converted into soft water, and the generated soft water is discharged through the outgoing channel of the column to the user do.

In addition, the water softener requires a regeneration process. In this regeneration process, sodium chloride is filled in the one side of the ion exchange resin filter for regeneration, the raw water is introduced into the inside of the housing to dissolve sodium chloride to produce salt water, (Na) ions in the dissolved salt water and the hardness component are passed through the ion exchange resin filter to recover the hardness removal performance of the ion exchange resin.

However, in the conventional water softener, the regeneration bath has an inlet flow channel to which external water is supplied and an outlet flow channel connected to the column. As described above, the inflow channel and the outflow channel connected to the regeneration tank form a complicated flow path inside the water softener, which causes a space limitation in the water softener and an increase in manufacturing cost.

It is an object of the present invention to provide a water softener system which can simplify the flow path around the regeneration tank to improve space utilization and thus reduce manufacturing costs.

According to an aspect of the present invention, there is provided an ion exchange resin filter for converting raw water supplied through a raw water supply passage into soft water using an ion exchange resin filled therein; A regeneration tank for storing a regenerant for regenerating the ion exchange resin of the ion exchange resin filter and supplying raw water introduced through the raw water supply flow channel to the ion exchange resin filter to regenerate the ion exchange resin filter; And a flow path switching unit installed between the regeneration tank and the ion exchange resin filter for switching the direction of the flow path between the regeneration tank and the ion exchange resin filter.

Preferably, the flow path switching portion includes a regeneration water inlet valve provided in the raw water supply flow passage for selectively blocking raw water flowing into the regeneration bath; A first flow path connected between the regeneration bath valve and the regeneration bath; A second flow path connecting the first flow path and the ion exchange resin filter; And a check valve installed in the second flow path so as to form a flow path direction only from the first flow path toward the second flow path, and when the regeneration air intake valve is opened, When the raw water is introduced into the regeneration tank and the regeneration water inlet valve is closed, raw water containing the regeneration agent is supplied from the regeneration tank through the first flow path and the second flow path to the ion exchange resin filter .

More preferably, the flow rate sensor is installed in the raw water supply passage; And a control unit for accumulating the flow rate sensed by the flow rate sensor and determining the regeneration point of the ion exchange resin filter through the integrated flow rate to control the regeneration bath valve.

The apparatus may further include a pump for supplying a fluid to the second flow path and discharging air into the second flow path toward the ion exchange resin filter.

Preferably, the fluid is a cleaning liquid.

The ion exchange resin filter may further include a drain valve for discharging water to the outside, and when the drain valve is opened after a predetermined amount of water is introduced into the regeneration tank, the pressure inside the ion exchange resin filter is released, And water is introduced into the ion exchange resin filter from the regeneration tank.

Preferably, the raw water supply passage is provided with a four-way valve for supplying raw water supplied from an external water supply source to the ion exchange resin filter and discharging the soft water generated from the ion exchange resin filter to an external water supply port, A pressure reducing valve for reducing the pressure of the raw water passing through the valve, a cadmium filter for filtering the raw water having passed through the pressure reducing valve, and an inlet valve for supplying raw water having passed through the cadmium filter to the ion exchange resin filter .

According to the present invention, the flow path is formed around the regeneration tank so that the raw water can flow in and out only through one outlet provided in the regeneration tank, so that the flow path can be simplified and the space utilization can be increased.

1 is a conceptual diagram schematically showing a configuration of a water softener system according to the present invention;
2 is a block diagram showing a control system diagram of a water softener system according to the present invention;

Hereinafter, preferred embodiments of a water softener system according to the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, it is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the technical scope of the present invention. Will be.

FIG. 1 is a conceptual diagram schematically showing a configuration of a water softener system according to the present invention, and FIG. 2 is a block diagram showing a control system diagram of a water softener system according to the present invention. 1 and 2, a water softener system according to the present invention includes an ion exchange resin filter 110a, 110b, a regeneration bath 120, and ion exchange resin filters 110a, 110b and a regeneration bath 120 And a flow path switching portion for switching the flow path.

The ion exchange resin filters 110a and 110b are cylindrical members each having a water inlet 111 and a water outlet 112, and the inside thereof is filled with an ion exchange resin. The raw water supplied through the raw water supply flow path is converted into soft water by passing through the ion exchange resin filters 110a and 110b while hardness components such as calcium ion and magnesium ion are ion exchanged with the chemical functional groups of the ion exchange resin. Here, the ion exchange resin filters 110a and 110b are made of the ion exchange resin filter 110a for warm water and the ion for cold water (for example, water) for the hot water and cold water supplied from the external hot water supply source 10a and the cold water supply source 10b, Exchange resin filter 110b.

The raw water supply flow path is a flow path provided between the external water supply sources 10a and 10b and the ion exchange resin filters 110a and 110b and includes an external hot water supply source 10a and a hot water exchange resin filter And a channel provided between the external cold water supply source 10b and the cold water ion exchange resin filter 110b. In addition, four-way valves 130a and 130b, depressurization sides 140a and 140b, cedilla filters 150a and 150b, and a water intake valve 160 are installed in the raw water supply channel.

The four-way valves 130a and 130b supply the raw water supplied from the water supply sources 10a and 10b to the ion exchange resin filters 110a and 110b. In addition, the four-way valves 130a and 130b discharge the soft water generated in the ion exchange resin filters 110a and 110b to the outer water outlet 20. The four-way valves 130a and 130b include a four-way valve 130a for warming and a four-way valve 130b for cold water.

The decompression sides 140a and 140b reduce the pressure of the raw water that has passed through the four-way valves 130a and 130b to prevent damage to the internal parts of the water softener. These pressure-decreasing sides 140a and 140b include a pressure-reducing side 140a and a pressure-reducing side 140b for cold water.

The seden filters (150a, 150b) are filters for removing chlorine and germs in raw water, which is generally tap water, having elements such as a chlorine removal ball and an antibacterial ball inside. The raw water passing through the decompression sides (140a, 140b) do. These three filters 150a and 150b include a warm-up sub-filter 150a and a cold-water sub-filter 150b.

The inlet valve 160 serves to supply raw water filtered through the sedi filter 150a and 150b to the ion exchange resin filters 110a and 110b.

The raw water is introduced into the ion exchange resin filters 110a and 110b through the raw water supply passages through the external water supply sources 10a and 10b and the introduced raw water is converted into the soft water through the ion exchange resin filters 110a and 110b And is discharged to the outside through the water outlet 20.

The regeneration tank 120 stores a regenerant for regenerating the ion exchange resin of the ion exchange resin filters 110a and 110b. The regeneration tank 120 is supplied with raw water through a channel 30 bypassed from a channel provided between a raw water supply channel, more precisely, between the cold water supply source 10b and the cold water ion exchange resin filters 110a and 110b . The raw water flowing into the regeneration tank 120 is supplied to the ion exchange resin filters 110a and 110b in a state containing the regenerant in the regeneration tank 120. [ Therefore, the ion exchange resins of the ion exchange resin filters 110a and 110b are regenerated.

On the other hand, a flooding channel (40) is connected to one side of the regeneration tank (120). The overflow channel (40) allows the overflowing water in the regeneration tank (120) to be discharged to the outside.

The flow path switching unit is provided between the regeneration tank 120 and the ion exchange resin filters 110a and 110b to switch the direction of the flow path between the regeneration tank 120 and the ion exchange resin filters 110a and 110b. Here, the flow path switching unit is configured to allow raw water to flow in and out through the single outlet 121 provided in the regeneration tank 120. That is, the channel switching unit allows one outlet 121 provided in the regeneration tank 120 to be used as a raw water inlet to the regeneration tank 120 and a raw water outlet from the regeneration tank 120.

Specifically, the flow path switching section includes a regeneration water inlet valve 170, a first flow path 50, a second flow path 60, and a check valve 180.

The regeneration water supply valve 170 is installed in the raw water supply flow path, more precisely the flow path 30 bypassed from the raw water supply flow path, and selectively blocks the raw water flowing into the regeneration tank 120.

The first flow path 50 connects the regeneration tank valve 170 and the regeneration tank 120. When the regeneration tank valve 170 is opened, the regeneration tank 120 is connected to the regeneration tank 120 through the first flow path 50, As shown in FIG.

The second flow path 60 connects the first flow path 50 and the ion exchange resin filters 110a and 110b. The second flow path 60 is connected to the ion exchange resin filters 110a and 110b and the ion exchange resin filters 110a and 110b for cold water that are bypassed in the first flow path 50, 120, the raw water containing the regenerant is introduced into the ion exchange resin filters 110a, 110b.

The check valves 180a and 180b are provided on the inlet side of the second flow path 60 and precisely the ion exchange resin filters 110a and 110b so that the raw water containing the regenerant discharged from the regeneration tank 120 is subjected to ion exchange And flows into the resin filters 110a and 110b. Here, the check valves 180a and 180b allow the flow direction of the raw water to flow from the first flow path 50 toward the second flow path 60 only. The check valves 180a and 180b are provided on the inlet side of the ion-exchange resin filter 110a for warm water and the ion exchange resin filter 110b for cold water, respectively. These check valves 180a and 180b may be constituted by general ON / OFF valves.

When the regeneration water inlet valve 170 is opened, raw water introduced from the cold water supply source 10b flows into the regeneration tank 120 via the regeneration water valve 170 and the first flow path 50, Lt; / RTI > Here, the raw water flowing in the direction of the regeneration tank 120 flows into the first flow path 50 without being introduced into the second flow path 60 by its own pressure and by the pressure inside the ion exchange resin filters 110a, 110b. And is introduced into the regeneration tank 120 only through the regeneration tank 120. At this time, the water in the ion exchange resin filters 110a and 110b does not flow back to the second flow path 60 due to the check valves 180a and 180b.

When the regeneration water supply valve 170 is closed, the raw water inside the regeneration tank 120 flows into the ion exchange resin filters 110a and 110b through the first flow path 50 and the second flow path 60 .

As described above, according to the water softener system of the present invention, the flow path switching unit allows the raw water to flow in and out through one outlet 121 provided in the regeneration tank 120. Therefore, the flow path around the regeneration tank 120 can be easily configured, thereby increasing the space utilization in the water softener and reducing the overall manufacturing cost.

Preferably, the water softener system according to the present invention further includes a controller 200 for controlling the regeneration water inlet valve 170 according to the detection results of the flow rate sensor 190 and the flow rate sensor 190.

The flow rate sensor 190 is disposed between the depressurization side 140b of the raw water supply flow passage, the sub filter 150b and the regeneration water supply valve 170 to measure the flow rate of the raw water introduced into the raw water supply flow passage.

The control unit 200 accumulates the raw water flow rate measured through the flow rate sensor 190 and determines that it is necessary to regenerate the ion exchange resin filters 110a and 110b when the accumulated flow rate reaches a predetermined value, And controls the regeneration water supply valve 170 to be opened. Therefore, periodic regeneration of the ion exchange resin filters 110a and 110b is possible.

On the other hand, air may flow into the second flow path 60 from the regeneration tank 120. If air exists in the second flow path 60, the raw water discharged from the regeneration tank 120 flows through the ion exchange resin filter (110a, 110b). In order to prevent this, the water softener system according to the present invention further includes a pump 210 for supplying a fluid to the second flow path 60. The pump 210 supplies the fluid into the second flow path 60 to discharge the air inside the second flow path 60 to the outside.

Preferably, the fluid pumped to the second flow path 60 by the operation of the pump 210 is the cleaning liquid 211. The cleaning liquid flows into the ion exchange resin filters 110a and 110b to clean the flow path.

On the other hand, a predetermined internal pressure is formed in the ion exchange resin filters 110a and 110b by the stored ion exchange resin and water, and this pressure hinders the smooth inflow of the raw water introduced from the regeneration tank 120. In order to release this internal pressure, a drain passage 70 is provided on one side of the ion exchange resin filters 110a and 110b and a hot water drain valve 115a and a cold water drain valve 115b are provided on the drain passage 70 . After a predetermined amount of water has been introduced into the regeneration tank 120 through the regeneration water inlet valve 170, the water discharge valves 115a and 115b are opened to release the pressure inside the ion exchange resin filters 110a and 110b .

Therefore, the raw water discharged from the regeneration tank 120 can flow smoothly into the ion exchange resin filters 110a and 110b.

The embodiments of the present invention described above are merely illustrative of the technical idea of the present invention, and the scope of protection of the present invention should be interpreted according to the claims. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It should be interpreted that it is included in the scope of right.

10a, 10b: Water source 20: Water source
30, 40, 50, 60, 70: flow path 110a, 110b: ion exchange resin filter
111: inlet 112: outlet
115a, 115b: drain valve 120: regeneration tank
121: Outlets 130a, 130b: Four-way valve
140a, 140b: Pressure reducing sides 150a, 150b:
160: water inlet valve 170: regeneration water inlet valve
180a, 180b: check valve 190: flow rate sensor
200: control unit 210: pump

Claims (7)

An ion exchange resin filter for converting the raw water supplied through the raw water supply passage into soft water using an ion exchange resin filled therein;
A regeneration tank for storing a regenerant for regenerating the ion exchange resin of the ion exchange resin filter and supplying raw water introduced through the raw water supply flow channel to the ion exchange resin filter to regenerate the ion exchange resin filter; And
And a flow path switching unit installed between the regeneration tank and the ion exchange resin filter for switching a direction of a flow path between the regeneration tank and the ion exchange resin filter.
The method according to claim 1,
Wherein the flow-
A regeneration water supply valve installed in the raw water supply passage to selectively block raw water flowing into the regeneration tank;
A first flow path connected between the regeneration bath valve and the regeneration bath;
A second flow path connecting the first flow path and the ion exchange resin filter; And
And a check valve installed in the second flow path so that a flow direction is formed only from the first flow path toward the second flow path,
When the regeneration water inlet valve is opened, raw water flows into the regeneration tank through the first flow path, and when the regeneration water valve is closed, raw water containing the regeneration agent in the regeneration tank is discharged from the regeneration tank Wherein the water is introduced into the ion exchange resin filter through the first flow path and the second flow path.
3. The method of claim 2,
A flow rate sensor installed in the raw water supply passage; And
Further comprising a controller for integrating the flow rate sensed by the flow rate sensor and determining the regeneration point of the ion exchange resin filter through the integrated flow rate to control the regeneration bath valve.
3. The method of claim 2,
Further comprising a pump for supplying a fluid to the second flow path and discharging air to the ion exchange resin filter side in the second flow path.
5. The method of claim 4,
Wherein the fluid is a cleaning liquid.
5. The method of claim 4,
Wherein the ion exchange resin filter is provided with a drain valve for discharging water to the outside, and when the drain valve is opened after a predetermined amount of water is introduced into the regeneration tank, the pressure inside the ion exchange resin filter is released, Wherein water is introduced into the ion exchange resin filter from the ion exchange resin filter.
The method according to claim 1,
Wherein the raw water supply passage is provided with a four-way valve for supplying raw water supplied from an external water supply source to the ion exchange resin filter and discharging the soft water generated from the ion exchange resin filter to an external water supply passage, And a water inlet valve for supplying the raw water having passed through the sedi filter to the ion exchange resin filter. The water softener according to claim 1,

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