KR20130011447A - Water purifier - Google Patents

Abstract

PURPOSE: A water purifier is provided minimize the sterilization time for bactericidal action when the sterilization components in the water are high and provide water purification when the fur sandwiched in the water tub are together removed using high temperature. CONSTITUTION: A water purifier composes of water purifying part(1), a water tub, an electrolysis sterilizer(52), a heater(60), circulated disinfected milk(70) and a pump(80). The water tube comprises of an ice bath(20) and water tank(12) and the sterilized water is put into a water tank. The water of the water tank flows into the iced bath and is cooled. The electrolysis sterilizes the electrolytes in the water and the sterilized component is produced. The heater heats the water and it transmits and sterilizes the fish louse in the water tub. The circulation of disinfected milk furnace connects these and the water is ventilated. The heater, pump and the electrolysis sterilizer is turned on when the sterilization mode is turned on together.

Description

 Water Purifier

The present invention relates to a water purifier, and more particularly, to a water purifier capable of sterilizing a water tank with an electrolytic sterilizer.

In general, a water purifier is a device that removes impurities and filters them by physical and chemical methods.

Water purifiers can be classified into natural filtration, direct filtration, ion exchange resin, distillation, reverse osmosis, etc.

Water purifiers are classified according to the type of storage water purifier that passes through the filter and stores the purified purified water in a water tank, and discharges it by heating or cooling. There is.

Recently, a sterilizer is installed in a water purifier to sterilize a reservoir with a sterilizer.

KR 10-0621937 (September 14, 2006)

Since the water purifier according to the prior art is contained in the water purification tank after the water passing through the filter unit passes through the electrolytic cell sterilizer, there is a problem in that the capacity and cost of the electrolytic cell sterilizer are increased to generate a large amount of sterilizing material.

The present invention is a water purification unit for purifying water; A water tank including a water tank containing water purified by the water purification unit and a cold water tank into which water of the water tank is introduced and cooled; An electrolytic sterilizer which electrolyzes water to generate sterilization components; A heater for heating water; A circulating sterilization flow path through which the water in the tank circulates the electrolytic sterilizer, the heater and the water tank; It is installed in the circulating sterilization flow path includes a pump for circulating water.

The pump may be installed between the electrolytic sterilizer and the heater in the circulating flow direction of the water.

The circulating sterilizing oil may be connected to a water tank inflow channel for guiding the water passing through the water purification unit to the water storage tank or to the water storage tank, and a cold water water flow channel for discharging water from the cold water tank or the other end to the cold water tank. .

The tank inlet flow passage may be provided with a check valve to prevent water from flowing to the water purification unit when circulating the electrolytic sterilizer, the heater and the tank.

The circulation sterilization oil passage includes an electrolytic sterilizer flow passage for guiding water to the electrolytic sterilizer, an electrolytic sterilizer flow passage for guiding water passing through the electrolytic sterilizer, and a heater inlet flow passage for guiding water to the heater; ; It may include a heater discharge passage for guiding the water passing through the heater.

The pump may be connected to the electrolytic sterilizer outlet channel and the heater inlet channel.

A drain passage connected to the circulation sterilization passage; It may further include a drain control valve for controlling the water passing through the heater flows to the cold water tank or the water of the cold water tank is drained into the drain flow channel.

The drain control valve may be a three-way valve installed in the heater discharge passage between the heater and the cold water tank and connected to the drain passage.

The water purifying unit includes a plurality of filters which are purified while passing water sequentially, wherein the water purifier bypasses at least a portion of the plurality of filters and guides water to at least one of the water tank and the sterilization circulation passage. The instrument can be connected.

The bypass mechanism includes a bypass feed passage connected to at least one of the water tank and the sterilization circulation passage; It may include a bypass control valve for controlling the water passing through any one of the plurality of filters to be flowed into the bypass feed passage or to another of the plurality of filters.

The bypass control valve may be a three-way valve installed in a filter connection flow path connecting any one of the plurality of filters and the other and connected to the bypass water supply flow path.

The water purifier of the present invention includes a water purifying part including a plurality of filters which are purified while passing water sequentially and a pump is installed in a filter connection flow path connecting any one of the plurality of filters to the other; A water tank including a water tank containing water purified by the water purification unit and a cold water tank into which water of the water tank is introduced and cooled; An electrolytic sterilizer which electrolyzes water to generate sterilization components; A heater for heating water; The water of the tank may include a circulating sterilization flow path that is pumped by the pump and passed through the electrolytic sterilizer and the heater to be obtained into the tank.

The electrolytic sterilizer, heater and pump may be turned on together in the sterilization mode.

The heater may be installed after the electrolytic sterilizer in the circulating flow direction of the water.

The circulating sterilization oil passage includes a cold water discharge passage capable of withdrawing water from the cold water tank, and a water tank discharge passage connecting one of the cold water tanks and the transfer of the pump among the filter connection passages; An electrolytic sterilizer acquisition passage connecting the electrolytic sterilizer to the after of the pump in the filter connecting passage; An electrolytic sterilizer discharge passage connecting the electrolytic sterilizer and the heater; It may include a water tank inlet channel for guiding the water passing through the water purification unit to the water tank and a heater water outlet channel for connecting one of the water tank and the heater.

 It may include a circulation and water supply control valve is installed in the filter connection flow passage to allow the water passing through any one of the plurality of filters to flow to the pump or to allow the water in the tank outlet flow path to flow to the pump.

It may include a circulation and purified water control valve installed in the filter connection flow passage to allow the water passed through the pump to flow to the other of the plurality of filters or to the electrolytic sterilizer inlet flow passage.

A drain passage connected to the circulation sterilization passage; It may further include a drain valve for regulating the water passing through the drain passage.

In the present invention, since the water of the tank circulates the electrolytic sterilizer, the heater and the water tank, the electrolyzed and heated water sterilizes the tank, so that the sterilization effect of the sterilization component contained in the water is high and the sterilization time can be minimized. have.

In addition, by the high temperature of the water containing the sterilization component there is an advantage that can be removed together with the scale stuck in the tank.

1 is a view showing the configuration of the first embodiment of the water purifier according to the present invention;
2 is a control block diagram of a water purifier according to a first embodiment of the present invention;
3 is a view showing the water flow at the time of withdrawal of the first embodiment of the water purifier according to the present invention;
4 is a view showing the water flow during water drainage of the first embodiment of the water purifier according to the present invention;
5 is a view showing the water flow during water supply of the first embodiment of the water purifier according to the present invention;
6 is a view showing the water flow during the sterilization of the water tank of the first embodiment of the water purifier according to the present invention;
7 is a view showing the configuration of a second embodiment of a water purifier according to the present invention;
8 is a view showing the configuration of a third embodiment of the water purifier according to the present invention;
9 is a view showing the water flow at the time of withdrawal of the third embodiment of the water purifier according to the present invention;
10 is a view showing the water flow during water drainage of the third embodiment of the water purifier according to the present invention;
11 is a view showing the water flow during water supply of the third embodiment of the water purifier according to the present invention;
12 is a view showing the water flow in the sterilization of the water tank of the third embodiment of the water purifier according to the present invention.

1 is a diagram showing the configuration of a first embodiment of a water purifier according to the present invention.

As shown in FIG. 1, the water purifier includes a water purifying part 1 for purifying water; A water tank 40 including a water storage tank 12 containing water purified by the water purification unit 1 and a cold water tank 20 into which water of the water storage tank 12 is introduced and cooled; After the electrolysis and heating the water in the water tank 40 may be recovered to the water tank 40 may include a water tank sterilizer (50) for sterilizing the water tank (40).

The water purification unit 1 may include a plurality of filters 2, 3, 4 that are purified while water sequentially passes through.

The plurality of filters (2), (3) and (4) may be at least two filters connected in stages to purify water.

The plurality of filters (2) (3) (4) include a sediment filter, a line carbon filter, a reverse osmosis membrame filter or an ultra filtration membrane filter and a post carbon filter. Can be configured in various combinations.

In the plurality of filters 2, 3, and 4, any one filter 2 may be composed of a sediment filter or a pre carbon filter. The other filter (3) through which the purified water passes through may be composed of a Reverse Osmosis membrame filter or an Ultra Filtration membrame filter, and the other filter (3) Another filter 4 through which purified water passes may be configured as a post carbon filter.

The water purification unit 1 may be connected to any one filter (2) of the plurality of filters (2) (3) (4) and the other filter (3) through the filter connection passage (6) (7) (8) The other filter 3 and the other filter 4 of the plurality of filters 2, 3, and 4 may be connected to the other filter connection channel 9.

Hereinafter, it can be demonstrated that the some filter 2, 3, 4 is three filters. That is, the plurality of filters (2) (3) (4) are the first filter which is any one of the filters (2) (3) and (4), and the plurality of filters (2) (3). (4) may include a second filter, which is the other filter 3, and a plurality of filters (2), (3), and (4) may include a third filter which is the other filter 3 of the following. For convenience of description, like the first filter 2, the second filter 3, and the third filter 4, the same reference numerals may be used.

The water supply unit 5 may be connected to the water supply unit 5 for guiding water to the water purification unit 1.

The raw water supply flow passage 5 guides the water supplied from the outside such as tap water to be purified by the water purification unit 1, and may be connected to the first filter 2.

The first filter 2 may be connected to the second filter 3 through filter connection flow paths 6, 7 and 8.

The filter connecting passages 6, 7 and 8 may include a feed valve 6 for intermittent water flowing from the first filter 2 toward the second filter 3.

The filter connection passages 6, 7 and 8 connect the water supply valve inlet 7 connecting the first filter 2 and the water supply valve 6, the water supply valve 6, and the second filter 3. The water supply valve may include a water flow passage (8).

 The second filter 3 may be connected to another filter connecting passage 9 from the third filter 4.

The water purification unit 1 may be connected to the water tank inlet 10 for guiding the water passing through the water purification unit 1 to the water tank 40.

The water tank inlet 10 may be disposed between the purified water unit 1 and the reservoir 12 to guide the purified water from the purified water unit 1 to the reservoir 12. One end of the reservoir inflow channel 10 may be connected to the third filter 4, and the other end thereof may be connected to the reservoir 12.

The reservoir 12 is a reservoir tank in which water purified from the purified water unit 1 is contained.

The reservoir 12 may be connected to the purified water discharge passages 13 and 14 capable of withdrawing water contained in the reservoir 12 after being purified by the purified water unit 1.

The purified water discharge passages 13 and 14 may be provided with a purified water valve 16 to intercept water discharged from the reservoir 10 to the purified water discharge passages 13 and 14. The purified water valve 16 may be a solenoid valve.

The purified water outlet passage 13 and 14 may include a purified water valve inlet passage 13 before the purified water valve 16 and a purified water valve outlet passage 14 after the purified water valve 16 in a direction in which water is discharged. have.

The reservoir 12 may be provided with a water level sensor 18 for detecting the water level of the water tank (40).

The cold water tank 20 is a cooling tank unit in which the water flowing in the water storage tank 12 is cooled.

The cold water tank 20 is formed integrally with the water storage tank 12 at the lower side of the water storage tank 12 to receive water dropped from the water storage tank 12, and the water storage tank 12 and a separate cold water tank inflow channel (not shown) It is possible to receive the water of the reservoir 12 through the cold water tank inlet flow path.

The cold water tank 20 may be connected to a cooling device 22 for cooling the water of the cold water tank 20.

The cooling device 22 may include a compressor for compressing a refrigerant, a condenser for condensing the refrigerant compressed in the compressor, an expansion mechanism for expanding the refrigerant condensed in the condenser, and an evaporator for evaporating the refrigerant expanded in the expansion mechanism. have.

The cooling apparatus may be disposed inside the cold water tank 20 or may be disposed on the outer wall of the cold water tank 20, and the refrigerant may cool the water in the cold water tank 20 while being evaporated when passing through the evaporator.

The cold water tank 20 may be connected to the cold water discharge passages 23 and 24 capable of withdrawing the water contained in the cold water tank 20.

The cold water outlet passages 23 and 24 may be provided with a cold water valve 26 to control the water discharged from the cold water tank 20 to the cold water outlet passages 23 and 24. The cold water valve 26 may be a solenoid valve.

The cold water outlet passages 23 and 24 may include a cold water valve inlet passage 23 before the cold water valve 26 and a cold water valve outlet passage 24 after the cold water valve 26 in a direction in which water is discharged. have.

 The water tank 40 may be connected to the hot water tank 30 in which the water of the reservoir 12 is introduced and cooled.

The hot water tank 30 is a heating tank unit in which the water flowing in the reservoir 12 is heated.

The hot water tank 30 is directly connected to the water storage tank 12 at the lower side of the water storage tank 12 to hold water dropped from the water storage tank 12, and connected to the water storage tank 12 and the hot water tank inlet flow passage 31. It is possible to receive the water of the reservoir 12 through the hot water tank inlet flow passage 31.

The hot water tank inlet 31 has a check valve 32 that prevents the water of the hot water tank 30 from flowing into the water tank 12 while allowing the water of the water tank 12 to flow into the hot water tank 30. Can be installed.

The hot water tank 30 may be provided with a hot water heater 33 for heating the water of the hot water tank (30).

The hot water tank 30 may be connected to the hot water discharge passages 34 and 35 capable of withdrawing the water contained in the hot water tank 30.

The hot water outlet passage 34 and 35 may be provided with a hot water valve 36 to control the water discharged from the hot water tank 30 to the hot water outlet passage 34, 35. The hot water valve 36 may be a solenoid valve.

The hot water discharge passage 34 and 35 may include a hot water valve inlet passage 34 before the hot water valve 36 and a hot water valve outlet passage 35 after the hot water valve 36 in a direction in which water is discharged. have.

  The water purifier may include a common discharge passage 37 to which the purified water discharge passage 13 and 14, the cold water discharge passage 23, 24, and the hot water discharge passage 34 and 35 are connected.

The common water flow passage 37 includes purified water through which one flow path passes through the purified water discharge passages 13 and 14, purified water and cooled water passing through the cold water discharge passages 23 and 24, and a hot water discharge passage. The purified water and the heated water passing through (34) and (35) can be discharged to the outside.

The tank sterilizer 50 includes an electrolytic sterilizer 52 which electrolyzes water to generate sterilization components; A heater 60 for heating water; A circulating sterilization flow path 70 through which water in the water tank 40 circulates the electrolytic sterilizer 52, the heater 60, and the water tank 40; A water purifier including a pump 80 installed in the circulation sterilization flow path 70 to circulate water.

The electrolytic sterilizer 52 is capable of sterilizing the water tank 40 including the water storage tank 12 and the cold water tank 20. The electrolytic sterilizer 52 can change the chlorine ions in the water into hypochlorite ions, which are sterilization components by electrolyzing water. have.

The electrolytic sterilizer 52 includes a housing and an anode and a cathode spaced apart from the inside of the housing, wherein the housing has a water inlet for guiding water to flow between the anode and the cathode, and the water passed between the anode and the cathode is discharged. The water exit portion may be formed.

The electrolytic sterilizer 52 is preferably turned on together with the heater 60 and the pump 80 in the sterilization mode, and the heater 60 and the pump 80 in the non-sterile mode such as purified water, cold water, or hot water output. It is preferred to be off together.

 The heater 60 may heat the electrolyzed water while passing through the electrolytic sterilizer 52, or preheat the water flowing toward the electrolytic sterilizer 52.

The heater 60 is capable of increasing the sterilizing power of the water tank 40 by hypochlorite ions, which are sterilizing components. When the water electrolyzed by the electrolytic sterilizer 52 is heated by the heater 60 and heated, Water can weaken the cell wall of bacteria, and hypochlorite ions contained in hot water can more easily remove bacteria that have weakened cell walls.

When the water is heated to approximately 10 ° C by the heater 60, hypochlorite ions contained in the water can improve the bactericidal ability of the bacteria approximately two to three times.

The circulating sterilization flow path 70 may connect the water tank 40, the electrolytic sterilizer 52, and the heater 60.

The circulating sterilization flow path 70 allows the water in the water tank 40 to form a water circulation flow path for returning to the water tank 40 after passing through the electrolytic sterilizer 52 and the heater 60. It is possible to continuously sterilize the water tank 40 while circulating.

The circulating sterilization flow path 70 may be formed such that water in the water tank 40 is first electrolyzed in the electrolytic sterilizer 52 and then heated in the heater 60, and then returned to the water tank 40, and the water tank 40. It is possible that the water of) is first heated in the heater 60 and then electrolyzed in the electrolytic sterilizer 52, and then returned to the water tank 40.

That is, the circulating sterilization flow path 70 may be installed after the electrolytic sterilizer 52 in the circulating flow direction of water, and the electrolytic sterilizer 52 is located after the heater 60 in the circulating flow direction of water. It is possible to be installed on.

The circulating sterilization flow path 70 is electrolytic sterilizer 52 when the water in the water tank 40 is electrolyzed in the electrolytic sterilizer 52 and then the water heated in the heater 60 is returned to the water tank 40. The circulation sterilization flow path 70 may be higher, and more preferably, the heater 60 is installed after the electrolytic sterilizer 52 in the circulating flow direction of the water.

Hereinafter, it will be described that the heater 60 is installed after the electrolytic sterilizer 52 in the circulating flow direction of the water.

The circulating sterilization flow path 70 may be connected so that the pump 80 is installed before the electrolytic sterilizer 52 in the circulating flow direction of water, and between the electrolytic sterilizer 52 and the heater 60 in the circulating flow direction of water. It is possible to be connected to be installed in, it is possible to be connected to be installed after the heater 60 in the circulating flow direction of the water.

The circulating sterilization flow path 70 is the water heated by the heater 60 when the pump 80 is connected to be installed before the electrolytic sterilizer 52 or installed between the electrolytic sterilizer 52 and the heater 60. Damage to the pump 80 can be minimized.

In the circulating sterilization flow path 70, the pump 80 is preferably installed before the electrolytic sterilizer 52 or between the electrolytic sterilizer 52 and the heater 60. Hereinafter, the electrolytic sterilizer 52 and the heater 60 are used. It will be described taking as an example what is installed in between.

 The circulating sterilization flow path 70 may have one end 71 connected to the water tank acquisition flow path 10 or the storage tank 12.

The circulating sterilization flow path 70 may have the other end 72 connected to the cold water discharge flow paths 23 and 24 or the cold water tank 20. The circulation sterilization flow path 70 may be connected to the cold water valve inlet flow path 23 when the other end is connected to the cold water discharge flow paths 23 and 24.

The water purifier may return water to the water storage tank 12 after the water of the water storage tank 12 passes through the electrolytic sterilizer 52, the heater 60, and the cold water tank 20 in sequence, and the water of the cold water tank 20 After passing through the electrolytic sterilizer 52, the heater 60, and the reservoir 12 in sequence, it is possible to return to the cold water tank 20.

Hereinafter, it will be described that the water in the reservoir 12 passes through the electrolytic sterilizer 52, the heater 60, and the cold water tank 20 sequentially, and then returns to the reservoir 12.

The circulating sterilization flow path 70 includes an electrolytic sterilizer flow passage 73 for guiding water to flow into the electrolytic sterilizer 52, an electrolytic sterilizer water flow passage 74 for guiding water passing through the electrolytic sterilizer 52, and water. A heater inlet flow passage 75 for guiding flow to the heater 60; It may include a heater discharge passage 76, 77 guided by the water passing through the heater 60.

 The electrolytic sterilizer acquisition channel 73 may be connected to the tank acquisition channel 10 or the reservoir 12.

The electrolytic sterilizer outlet passage 74 and the heater inlet passage 75 may be connected to the pump 80.

The heater discharge passages 76 and 77 may be connected to the cold water discharge passages 23 and 24 or the cold water tank 20.

In operation, the pump 80 pumps water into the heater inflow channel 75, the water in the heater inflow channel 75 flows into the heater 60, and the water passing through the heater 60 passes through the heater outflow channel 76. It is introduced into the cold water tank 20 through the (77). The water introduced into the cold water tank 20 flows into the water storage tank 12, and the water flowed into the water storage tank 12 flows into the electrolytic sterilizer 52 through the electrolytic sterilizer acquisition channel 73, and the electrolytic sterilizer 52. The water passed through is introduced into the pump 80 through the electrolytic sterilizer discharge passage 74.

The water purifier drains all or part of the water in the water tank 40 to the outside before the sterilization mode is performed, and then supplies water to the water tank 40, and then sterilization mode is performed to electrolyze and water the water in the water tank 40. It is possible to sterilize the water tank 40 while heating, and sterilize the water tank 40 by electrolyzing and heating the water of the water tank 40 without draining the water of the water tank 40 to the outside of the water purifier prior to the execution of the sterilization mode. It is possible to let.

At least one of the plurality of filters (2), (3) and (4) may excessively lower the concentration of chlorine ions contained in the water. In this case, the water tank 40 and the electrolytic sterilizer 52 and The water circulating in the heater 60 may not reach the target concentration of hypochlorite as a sterilization component due to insufficient concentration of chlorine ions contained in the water, and reach the target concentration even if the sterilization component of hypochlorite is reached to the target concentration. It may take a long time.

The water purifier drains all or part of the water contained in the water tank 40 to the outside when the water contained in the water tank 40 before the sterilization mode is not suitable for electrolysis and the resulting sterilization component, and the chlorine contained in the water It is preferable to feed water not passing through the filter 3 which can excessively lower the concentration of ions to the water tank 40 or the circulating sterilization flow path 70.

The water purifier may include a drain passage 92 that may drain the water of the water tank 40.

The drainage flow path 92 is formed separately from the circulation sterilization flow path 70 to drain water from the water tank 40 to the outside, and is connected to the circulation sterilization flow path 70 to circulate the sterilization flow path 70 in the water tank 40. It is possible to drain the water that has flowed into part 77).

The drainage flow path 92 preferably drains the water flowed from the water tank 40 to a part 77 of the circulation sterilization flow path 70 to the outside in order to reduce the size of the water purifier and reduce the material cost. It will be described as being connected to.

The water purifier may include a drain control valve 94 for adjusting the water passing through the heater 60 to the cold water tank 20 or the water of the cold water tank 20 to be drained to the drain flow channel 92.

The drain control valve 94 may be configured as a three-way valve installed in the heater outlet passages 76 and 77 and to which the drain passage 92 is connected.

The heater outlet flow paths 76 and 77 are configured to connect the first heater outlet flow path 76 connecting the heater 60 and the drain control valve 94, and the drain control valve 94 and the cold water tank 20. 2 may include a heater exit passage (77).

When the drain control valve 94 communicates the second heater discharge channel 77 with the first heater discharge channel 76, the water in the water tank 40 is electrolytic sterilizer 52, the heater 60, and the drain control valve. 94 and the water tank 40 can be guided to circulate.

When the drain control valve 94 communicates the second heater discharge channel 77 with the drain channel 92, the water in the water tank 40 is discharged from the second heater discharge channel 77, the drain control valve 94, and the drainage valve. It may be guided to drain through the flow path 92.

The water purifier bypasses water to bypass at least some (3) (4) of the plurality of filters (2) (3) (4) and to feed water to at least some of the water tank (40) and the sterilization circulation passage (70). The instrument 100 can be included.

The bypass mechanism 100 preferably supplies water that has not yet passed through a filter that can excessively lower the concentration of chlorine ions contained in the water.

The bypass mechanism 100 does not pass through the reverse osmosis membrane filter in the water of the water purification unit 1 when the water purification unit 1 includes a reverse osmosis membrane filter capable of excessively lowering the concentration of chlorine ions contained in the water. It is preferable that the unfiltered water is installed to bypass the reverse osmosis membrane filter.

For example, when the second filter 3 of the plurality of filters 2, 3, 4 of the water purification unit 1 is a reverse osmosis membrane filter, the bypass mechanism 100 passes through the first filter 2. It is possible to guide the water of one water or the raw water supply flow passage 5 to be supplied to at least one of the water tank 40 and the sterilization circulation flow path 70 by bypassing the second filter 3 and the third filter 4. .

The bypass mechanism 100 bypasses all of the sieves and the water purification unit 1 in which the water of the raw water supply flow passage 5 does not pass through the first filter 2, so that in the water tank 40 and the sterilization circulation flow passage 70. When water is supplied to at least one, foreign matters contained in the water of the raw water supply flow path 5 may flow into the water tank 40 and the sterilization circulation flow path 70, so that the water passing through the first filter 2 passes through the second filter. It is preferable to guide the water supply to at least one of the water tank 40 and the sterilization circulation flow path 70 by bypassing the third filter and the third filter 4.

  The bypass mechanism 100 may include a bypass water supply passage 102 connected to at least one of the water tank 40 and the sterilization circulation passage 70.

When the bypass water supply passage 102 is connected to the water tank 40, it is directly connected to the water tank 40, and it is possible to directly supply water to the water tank 40, and is connected to the water tank inflow channel 10 and the water tank inflow channel ( 10) it is possible to feed water to the water tank (40).

When the bypass feed passage 102 is connected to the sterilization circulation passage 70, the electrolytic sterilizer inlet passage 73, the electrolytic sterilizer outlet passage 74, the heater inlet passage 75 and the heater outlet passage 76, 77 are provided. It can be connected to either.

The bypass mechanism 100 is configured such that the water passing through any one of the plurality of filters 2, 3, 4 flows into the bypass feed channel 102, or the plurality of filters 2, 3, ( 4) may include a bypass control valve 104 to be adjusted to flow to the other one (3).

Bypass control valve 104 is installed in the filter connecting passage (6) (7) (8) connecting any one (2) of the plurality of filters (2) (3) (4) and the other (3) The bypass water supply passage 102 may be formed of a three-way valve connected.

The bypass control valve 104 may be installed in the water supply valve inlet passage 7 of the filter connection passages 6, 7 and 8.

The water supply valve inflow passage 7 is a second water supply valve inflow passage 7a connecting the first filter 2 and the bypass control valve 104 to the bypass control valve 104 and the water supply valve. The water supply valve inlet passage 7b may be included.

When the bypass control valve 104 communicates the first water supply valve inlet 7a with the second water supply valve inlet 7b, the water passing through the first valve 2 is transferred to the second valve 3. Can be guided.

 When the bypass control valve 104 communicates the first water supply valve inlet 7a with the bypass water inlet 102, the water passing through the first valve 2 is guided to the bypass water inlet 102. Can be.

The water purifier prevents water circulating in the electrolytic sterilizer 52 and the heater 60 and the water tank 40 from flowing to the water purification unit 1 when the water circulates through the electrolytic sterilizer 52 and the heater 60 and the water tank 40. The check valve 106 may be installed in the water tank inlet 10.

When the water purifier includes one of the plurality of filters (2), (3), and (4) including a reverse osmosis membrane filter, the reverse osmosis membrane filter includes a filter drain passage 107 for draining a part of the water introduced into the reverse osmosis membrane filter. 108 may be connected.

The filter drain passages 107 and 108 include resistors 109 that allow all of the water introduced into the reverse osmosis membrane filter to not be drained to the filter drain passages 107 and 108 but partially pass through the reverse osmosis membrane filter. Can be arranged.

In this case, the resistor may have a smaller flow path area than the filter drain passages 107 and 108.

 The filter drainage passages 107 and 108 may be connected to the drainage passage 92.

The filter drain passages 107 and 108 may include a resistor inlet passage 107 between the reverse osmosis membrane filter and the resistor 109 and a resistor outlet passage 108 between the resistor and the drain passage 92.

Figure 2 is a control block diagram of a first embodiment of the water purifier according to the present invention, Figure 3 is a view showing the water flow when withdrawal of the first embodiment of the water purifier according to the present invention, Figure 4 is a first embodiment of the water purifier according to the present invention Example is a view showing the water flow during water drainage, Figure 5 is a view showing the water flow during water supply of the first embodiment of the water purifier according to the present invention, Figure 6 is the water during sterilization of the water tank of the first embodiment of the water purifier according to the present invention The flow is shown.

The water purifier may include a control unit 110 for controlling the water purifier and an input unit 102 for inputting a command by the user, and the control unit 110 may control the water purifier according to the input of the input unit 112 or the satisfaction of sterilization conditions. have.

 The control unit 110 includes a water supply valve 6, a water purification valve 16, a cooling device 22, a cold water valve 26, a hot water tank heater 33, a hot water valve 36, an electrolytic sterilizer 52 and a heater ( 60, the pump 80, the drain control valve 94, and the bypass control valve 104 may be controlled.

The water purifier has a water discharge mode in a purified water discharge mode, a cold water discharge mode and a hot water discharge mode, a drainage mode for draining the water in the water tank 40, and a water supply mode for supplying water to the water tank 40 or the sterilization circulation passage 90. And, it may have a sterilization mode for circulation sterilization inside the tank (40).

The control unit 110 according to each mode, the water supply valve (6), the water purification valve (16), the cooling device (22), the cold water valve (26), the hot water tank heater (33), the hot water valve (36) and the electrolytic sterilizer (52). ), The heater 60, the pump 80, the drain control valve 94, and the bypass control valve 104 may be controlled.

When the predetermined sterilization condition is satisfied, the water purifier can automatically perform a sterilization stroke for sterilizing the water tank 40. Here, the sterilization conditions may be various conditions such as a condition in which the operation time of the water purifier reaches an operation setting time, or a condition in which a time in which the water purifier does not discharge purified water or cold water reaches a non-outflow setting time.

When the water purifier inputs a sterilization command through the input unit 102, the water purifier can automatically perform a sterilization stroke for sterilizing the water tank 40.

Here, the sterilization stroke may include a first drainage mode step in which the water of the water tank 40 is partially or fully drained.

The sterilization stroke is followed by water supply to the water tank 40 or the circulating sterilization flow path 70 after the first drainage mode step, so that at least some of the plurality of filters 2, 3, 4 in the water tank 40 are at least partially discharged. It may include a water supply mode step in which the water bypassed by) is filled with water.

The sterilization stroke is electrolyzed and heated as the water in the water tank 40 passes through the electrolytic sterilizer 52 and the heater 60 after the water supply mode step, and the electrolyzed and heated water is returned to the water tank 40 so that the water tank 40 It may include a sterilization mode step of sterilizing).

The sterilization stroke may include a second drainage mode step in which all of the water in the water tank 40 is drained after the sterilization mode step.

The sterilization stroke may include a rinse mode step in which water for rinsing into the water tank 40 or the circulating sterilization flow path 70 is supplied after the second drainage mode step.

Here, the rinsing mode step may be performed in the same manner as the water supply mode step, and unlike the water supply mode step, the water tank of the raw water supply flow passage 5 passes through all of the plurality of filters 2, 3, 4, and then the tank It is possible to feed water to the 40 or the circulating sterilization flow path 70.

The sterilization stroke may include a third drainage mode step in which all the water in the water tank 40 is drained after the rinsing mode step.

When the predetermined sterilization condition is satisfied or a user inputs a sterilization command through the input unit 102, the water purifier includes a first drain mode step, a bypass water supply mode step, a sterilization mode step, a second drain mode step, a rinsing mode step, The third drainage mode step may be performed sequentially, and the water of the raw water supply flow passage 5 in the water purification unit 1 to be in a state capable of supplying purified water to the user after all of the above sterilization steps are completed. After purification, the purified water supply mode step of supplying the water tank 40 may be performed.

Hereinafter, the water extraction mode of the water purifier will be described.

In the water purifier, the controller 110 may open the purified water valve 16 in the purified water discharge mode. The controller 110 may drive or stop the cooling device 22 in the purified water discharge mode, and may close the cold water valve 26. The controller 110 may turn on or off the hot water heater 33 in the purified water discharge mode, and may close the hot water valve 36. The water purifier may turn off the electrolytic sterilizer 52, the heater 60, and the pump 80 in the purified water extraction mode. The controller 110 may control the bypass valve 104 in the non-drain mode in the purified water discharge mode, and control the drain control valve 94 in the non-drain mode.

Here, the non-bypass mode is a mode in which water passing through the first filter 2 flows toward the water supply valve 6 without flowing to the bypass flow path 102.

The non-drainage mode is a mode in which water in the circulating sterilization flow path 70 is circulated through the circulating sterilization flow path 70 without being drained to the drain flow path 92.

 When the user inputs the purified water output by inputting the input unit 112, the water inside the reservoir 12 passes through the purified water discharge passages 13 and 14 and the purified water valve 16, as shown in FIG. It is taken out. At this time, the water level of the reservoir 12 is lowered, the water level sensor 18 can detect that the water level of the reservoir 12 is lower than the water supply set level, the water level detected by the water level sensor 18 is below the water supply set level. The water supply valve 6 can be opened. When the water supply valve 6 is opened, the water of the raw water supply flow passage 5 is purified while passing through the first filter 2, the water supply valve 6, the second filter 3, and the third filter 4, and then the water tank It passes through the water supply passage 10 and is received into the water storage tank 12. As the new water is introduced into the reservoir 12, the water level of the reservoir 12 is increased, and the water level sensor 18 can detect that the reservoir 12 level reaches the full water level, and at the water level sensor 18 If the detected water level is a full water level, the water supply valve 6 may be closed.

In the cold water discharge mode, the control unit 110 may open the cold water valve 26 and drive or stop the cooling device 22. The control unit 110 may close the water purification valve 16 in the cold water discharge mode. You can. The controller 110 may turn on or off the hot water heater 33 in the cold water discharge mode, and may close the hot water valve 36. The water purifier may turn off the electrolytic sterilizer 52, the heater 60, and the pump 80 in the cold water discharge mode. The controller 110 may control the bypass valve 104 in the non-bypass mode in the cold water discharge mode, and control the drain control valve 94 in the non-drain mode.

 When the user inputs the cold water outlet by inputting the input unit 112, the water inside the cold water tank 20 passes through the cold water outlet passages 23 and 24 and the cold water valve 26 and is discharged to the outside. At this time, the water in the reservoir 12 flows to the cold water tank 20 as the water in the cold water tank 20 flows to the outside, the water level of the reservoir 12 is the water of the reservoir 12 to the cold water tank 20 Lower as much as it floats. The water purifier, as in the case of cold water discharge, when the water level sensor 18 detects the water level of the reservoir 12, and closes after the water supply valve 6 is opened as in the purified water discharge, it cleans and supplies new water. .

In the hot water discharge mode, the controller 110 may open the hot water valve 36 and turn the hot water heater 33 on or off. The controller 110 may drive or stop the cooling device 22 in the hot water discharge mode, and may close the cold water valve 26. The controller 110 may close the purified water valve 16 in the hot water discharge mode. The water purifier may turn off the electrolytic sterilizer 52, the heater 60, and the pump 80 in the hot water extraction mode. The controller 110 may control the bypass valve 104 in the non-bypass mode in the hot water discharge mode, and control the drain control valve 94 in the non-drain mode.

 When the user inputs the hot water outlet by inputting the input unit 112, the water inside the hot water tank 30 passes through the hot water discharge passage 34 and 35 and the hot water valve 36 and is discharged to the outside. At this time, the water in the reservoir 12 flows to the hot water tank 30 as the water in the hot water tank 30 flows to the outside, the water level of the reservoir 12 is the water of the reservoir 12 to the hot water tank 30 Lower as much as it floats. The water purifier is closed when the water level sensor 18 detects the water level of the reservoir 12, and when the water supply valve 6 is opened and closed, as in the case of the hot water discharge and the cold water discharge. Water is purified and watered.

Hereinafter, the drainage mode of a water purifier is demonstrated.

In the water discharge mode, the control unit 110 may close the water purification valve 16, the cold water valve 26, and the hot water valve 36 in the drainage mode, and turn on or off the cooling device 22 and the hot water heater 33. Can be. The controller 110 may turn off the electrolytic sterilizer 52, the heater 60, and the pump 80 in the drainage mode. The controller 110 may control the drain control valve 94 in the drain mode in the drain mode.

In the water purifying mode, as shown in FIG. 4, the water in the cold water tank 20 is drained to the drainage flow path 92 after being drained as part of the circulating sterilization flow path 70, wherein the water in the water storage tank 12 is As the water in the cold water tank 20 flows out to the outside, it is flowed to the cold water tank 20 and then drained to the outside through a part of the circulating sterilization flow path 70 and the drainage flow path 92.

In the water purifier, the water level sensor 18 detects the water tank of the reservoir 12 in the drainage mode, and the drainage mode may be performed until all of the water in the reservoir 12 is drained, and only a portion of the water in the reservoir 12 is discharged. It is possible for the drainage mode to be carried out until draining.

Hereinafter, the water supply mode of the water purifier will be described.

In the water supply mode, the controller 110 may close the water purification valve 16, the cold water valve 26, and the hot water valve 36 in the water supply mode, and turn on or off the cooling device 22 and the hot water heater 33. Can be. The controller 110 may turn off the electrolytic sterilizer 52 and the heater 60 in the water supply mode. The controller 110 may control the drain control valve 94 in the non-drain mode in the water supply mode. The controller 110 may control the bypass valve 104 in the non-bypass mode in the water supply mode. The controller 110 may turn on or off the pump 80 in the water supply mode.

In the water purifier, when the pump 80 is turned on in the water supply mode, water supplied from the bypass flow passage 102 sequentially passes through the electrolytic sterilizer 52 and the heater 60, and is then supplied to the cold water tank 30 to receive a water tank ( 40) and the pump 80 is not driven, the water to be supplied is supplied to the water tank 12 by the water pressure and filled in the water tank 40, or the electrolytic sterilizer 52 and the heater 60 in sequence After passing through the cold water tank 30 may be filled in the water tank (40).

In the water purifier, as shown in FIG. 5, the bypass valve 104 after the water in the raw water feed passage 5 passes through the first filter 2 of the plurality of filters 2, 3, and 4. ) Flows into the bypass flow path 102, and then flows into the circulation sterilization flow path 70 and is then supplied to the water tank 40.

In the water purifier, the water level sensor 18 detects the water tank of the reservoir 12 in the water supply mode, and when the water in the reservoir 12 reaches the full water level, the water supply mode may be completed.

   Hereinafter, the sterilization mode of the water purifier will be described.

In the sterilization mode, the controller 110 may close the purified water valve 16, the cold water valve 26, and the hot water valve 36, turn off the cooling device 22, and the hot water heater 33 in the sterilization mode. Can be turned on or off. The controller 110 may turn on the electrolytic sterilizer 52, the heater 60, and the pump 80 in the sterilization mode. The controller 110 may control the drain control valve 94 in the non-drain mode in the sterilization mode. The controller 110 may control the bypass valve 104 in the non-bypass mode in the sterilization mode.

As shown in FIG. 6 in the feed mode, the water of the reservoir 12 flows to the electrolytic sterilizer 52 to be electrolyzed, and the water includes hypochlorite ions, which are sterilizing components, while passing through the electrolysis. Water containing hypochlorite ions, which are sterilizing components, is pumped by the pump 80 to flow into the heater 60, heated by the heater 60, and then flows into the cold water tank 20 and the reservoir 12. Water electrolytically sterilizes the cold water tank 20 and the reservoir 12 while circulating the reservoir 12, the electrolytic sterilizer 52, the pump 80, the heater 60, the cold water tank 20, and the reservoir 12. The high temperature sterilization, the temperature is raised to high temperature, and the water containing hypochlorite ions as sterilization components can sterilize the cold water tank 20 and the water storage tank 12 with higher sterilizing power.

7 is a diagram showing the configuration of the second embodiment of the water purifier according to the present invention.

The water purifier of the present embodiment does not include a filter for excessively lowering the concentration of chlorine ions when the plurality of filters (2) (3) and (4) of the water purifying unit (1) bypass the water supply mechanism (100) of the first embodiment of the present invention. After the electrolysis and heating of the water in the water tank 40 can be recovered to the water tank 40 to sterilize the water tank 40, other configurations and actions other than the bypass water supply mechanism 100 is the first embodiment of the present invention Since the same or similar to the examples, the same reference numerals are used and detailed description thereof will be omitted.

The water purifier of the present embodiment has a plurality of filters (2) (3) (4) when the plurality of filters (2) (3) (4) of the water purifying unit (1) are composed of a sun carbon filter, a hollow fiber membrane membrane filter and a post carbon filter. The water passed sequentially may include chlorine ions sufficient for the generation of hypochlorite ions in the electrolytic sterilizer (52).

The water purifier of the present embodiment electrolytic sterilizes the water of the water tank 40 in the electrolytic sterilizer 52 without having to drain the water of the water tank 40 or supply new water to the water tank 40 during the sterilization stroke. It is possible to return to the water bath 40 after heating at.

In the water purifier of this embodiment, the sterilization stroke is electrolyzed and heated while the water in the water tank 40 passes through the electrolytic sterilizer 52 and the heater 60, and the electrolyzed and heated water is returned to the water tank 40 so that the water tank ( Sterilization mode step of sterilizing 40, and after the sterilization mode step, the first drainage mode step in which all the water in the tank 40 is drained, and after the second drainage mode step rinsing with the water tank 40 or the circulating sterilization flow path 70 A rinse mode step of supplying water for the rinsing mode step, and after the rinsing mode step may include a second drainage mode step in which all the water in the tank 40 is drained.

The rinsing mode step of the present embodiment may be carried out so that the water in the raw water supply flow passage 5 passes through all of the plurality of filters 2, 3, 4, and then is supplied to the water tank 40 or the circulating sterilization flow passage 70. have.

8 is a view showing the configuration of a third embodiment of the water purifier according to the present invention, Figure 9 is a view showing the water flow at the time of withdrawal of the third embodiment of the water purifier according to the present invention, Figure 10 is a water purifier according to the present invention Figure 3 is a view showing the water flow when water drainage of the third embodiment, Figure 11 is a view showing the water flow when water supply of the third embodiment of the water purifier according to the present invention, Figure 12 is a water tank sterilization of the third embodiment of the water purifier according to the present invention City water flow is shown.

 The water purifier of this embodiment includes a plurality of filters (2) (3) (4) in which the water purification unit (1) is purified while passing water sequentially, and any one of the plurality of filters (2) (3) (4). The pump 80 'may be installed in the filter connecting passages 7' and 8 connecting the second and the other ones (2).

The water purifier of the present embodiment may include the water tank 40, the electrolytic sterilizer 52, the heater 60, and the like, as in the first embodiment of the present invention, and the water tank 40, the electrolytic sterilizer 52, and the heater 60 Other configurations, such as), are the same as or similar to the first embodiment of the present invention, and detailed description thereof will be omitted.

The filter connecting passages 7 'and 8 are provided with a filter outlet passage 7c through which water passing through any one of the plurality of filters 2, 3, and 4 is pumped, and a pump 80'. It may include a pump inlet 7d for guiding the received water, and a pump outlet duct 7e for guiding the water discharged from the pump 80 '.

A water supply valve 6 for controlling water flowing toward the other one of the plurality of filters 2, 3, and 4 may be installed in the filter connection passages 7 ′ and 8. The flow paths 7 'and 8 may include a water supply valve connection flow path 7f for guiding water introduced into the water supply valve 6.

The filter connection passages 7 ′ and 8 may include a water supply valve discharge passage 8 connecting the other one 3 of the plurality of filters 2, 3, and 4 to the water supply valve 6. .

The pump 80 ′ may function as a kind of booster pump for increasing the water pressure when the raw water pressure such as tap water obtained by the water purifier is low.

As shown in the first embodiment of the present invention, the pump 80 'may allow the water of the water tank 40 to return to the water tank 40 after passing through the electrolytic sterilizer 52 and the heater 60 in sequence, and sterilizing. The mode may be turned on together with the electrolytic sterilizer 52 and the heater 60.

The water purifier of the present embodiment is a circulating sterilization flow path 120 connecting water so that the water in the water tank 40 is pumped by the pump 80 'and passed through the electrolytic sterilizer 52 and the heater 60 to be obtained into the water tank 40. It may include.

The circulating sterilization flow path 120 connects one of the cold water discharge flow paths 23 and 24 and the cold water tank 20 with the filter connection flow paths 7 'and 8 to form the cold water discharge flow paths 23 and 24 or the cold water. Water in the bath 20 may be pumped by the pump 80 'while passing through the filter connecting passages 7' and 8.

The circulating sterilization flow path 120 connects one of the water tank inflow path 10 and the reservoir 12 to the filter connection flow paths 7 'and 8 so that the water pumped by the pump 80' is provided with a plurality of filters 2. Bypassing at least a portion (3) (4) of the (3) (4) can be electrolyzed and heated and made available to the reservoir (12).

   The circulating sterilization passage 120 is a water tank outlet passage connecting one of the cold water outlet passages 23 and 24 and the cold water tank 20 and the transfer of the pump 80 'out of the filter connection passages 7' and 8 ( 121).

The water tank outlet passage 121 may be connected to one end of the cold water outlet passage 23, 24 or the cold water tank 20, and the other end thereof may be connected to a circulation and water supply control valve 130 described later.

The circulating sterilization flow path 120 may include an electrolytic sterilizer acquisition flow path 122 and 123 connecting the electrolytic sterilizer 52 to the after of the pump 80 'among the filter connection flow paths 7' and 8.

One end of the electrolytic sterilizer flow passages 122 and 123 may be connected to the circulation and purified water control valve 132, and the other end thereof may be connected to the electrolytic sterilizer 52 described later.

The circulation sterilization passage 120 may include an electrolytic sterilizer discharge passage 124 connecting the electrolytic sterilizer 52 and the heater 60.

The circulation sterilization passage 120 may include a heater outlet passage 125 connecting one of the water tank inlet 10 and the reservoir 12 to the heater 60.

The water purifier is installed in the filter connecting passages 7 'and 8 so that water passing through any one of the plurality of filters 2, 3 and 4 flows to the pump 80' or the tank outlet passage. It may include a circulation and feed water control valve 130 to allow the water of 121 to flow to the pump (80 ').

The circulation and water supply control valve 130 may be connected to the filter outlet passage 7c and the pump inlet passage 7d and may be connected to the water tank outlet passage 121.

As shown in FIGS. 9 and 11, the circulation and water supply control valve 130 has water passing through any one of the plurality of filters 2, 3, and 4 flows into the pump 80 ′. Or as shown in FIG. 12, the water in the tank outlet flow passage 121 may be flowed into the pump 80 ′.

Installed in the water purifier filter connection channel 7 'and 8, the water passing through the pump 80' flows to the other one of the plurality of filters 2, 3, 4, or the electrolytic sterilizer inlet channel. It may include a circulation and purified water control valve 132 to flow to (122) (123).

The circulation and purified water control valve 132 may be connected to the pump outlet channel 7e and the water supply valve connection channel 7f, and may be connected to the electrolytic sterilizer inlet channels 122 and 123.

 The circulation and purified water control valve 132 allows the water passing through the pump 80 'to flow to the other one of the plurality of filters 2, 3, 4, as shown in FIG. As shown in FIG. 11 and FIG. 12, water passing through the pump 80 ′ may be flowed into the electrolytic sterilizer inlet passages 122 and 123.

The water purifier may further include drain passages 92 'and 92 "connected to the circulating sterilization passage 120; and a drain valve 94' for controlling water passing through the drain passages 92 'and 92". Can be.

The drainage passages 92 ′ and 92 ″ may be connected to the water tank outlet passage 121 of the circulation sterilization passage 120, and the water of the tank 40 may be connected to the tank outlet passage 121 of the circulation sterilization passage 120. It may be drained out of the water purifier through the drain passages 92 'and 92 ".

The drain passages 92 'and 92 "are connected to the circulation sterilization passage 120 and the drain valve 94', and the drain valve inlet passage 92 'and one end of the drain valve 94' are connected to the drain valve. It may include a drain valve discharge flow path (92 ") for draining the water passed through 94 'to the outside of the water purifier.

The water purifier of the present embodiment is capable of pumping water to the other one of the plurality of filters (2), (3) and (4) regardless of the water pressure when the pump 80 'is in the water extraction mode. If low, it is possible to pump water into the other one 3 of the plurality of filters 2, 3, 4.

The pump 80 'may be turned on if the detected value of the flow sensor 134 is less than or equal to the set value in the discharge mode, depending on the detection result of the flow sensor 134 installed on one side of the filter connection passages 7' and 8. Do.

The water purifier of the present embodiment may be provided with a constant flow valve 136 in the circulation sterilization flow path 120, the constant flow valve 136 is installed between the pump 80 'and the electrolytic sterilizer 52 in the water circulation direction Can be. The constant flow valve 136 may be installed to allow a constant flow rate to the electrolytic sterilizer 52 regardless of a change in the pressure of the circulation sterilization flow path 120.

Hereinafter, the water extraction mode of the water purifier will be described.

The water purifier may open the purified water valve 16 in the purified water discharge mode. In the purified water discharge mode, the cooling device 22 may be driven or stopped, and the cold water valve 26 may be closed. The water purifier may turn on or off the hot water heater 33 in the purified water discharge mode, and may close the hot water valve 36. The water purifier may turn off the electrolytic sterilizer 52 and the heater 60 in the purified water extraction mode. The water purifier may turn on or off the pump 80 'in the purified water discharge mode. The water purifier can control the circulation and water supply control valve 130 in a non-circulating mode, and control the circulation and water purification valve 132 in a non-bypass mode in the water discharge mode, and the drain valve 94 'in a non-drain mode. Can be controlled by

Here, the non-bypass mode is a mode in which water passing through the first filter 2 flows toward the water supply valve 6.

The non-draining mode is a mode in which the water of the circulating sterilization channel 120 is not drained to the drain channels 92 'and 92 ".

 When the user inputs the purified water discharge, the water inside the reservoir 12 passes through the purified water discharge passages 13 and 14 and the purified water valve 16 and is discharged to the outside as shown in FIG. 9. At this time, the water level of the reservoir 12 is lowered, the water level sensor 18 can detect that the water level of the reservoir 12 is lower than the water supply set level, the water level detected by the water level sensor 18 is below the water supply set level. The water supply valve 6 can be opened. When the water supply valve 6 is opened, the water of the raw water supply flow passage 5 is purified while passing through the first filter 2, the water supply valve 6, the second filter 3, and the third filter 4, and then the water tank It passes through the water supply passage 10 and is received into the water storage tank 12. As the new water is introduced into the reservoir 12, the water level of the reservoir 12 is increased, and the water level sensor 18 can detect that the reservoir 12 level reaches the full water level, and at the water level sensor 18 If the detected water level is a full water level, the water supply valve 6 may be closed.

The water purifier may open the cold water valve 26 in the cold water discharge mode, the cooling device 22 may be driven or stopped, and the purified water valve 16 may be closed. The water purifier may turn on or off the hot water heater 33 in the cold water discharge mode, and may close the hot water valve 36. The water purifier may turn off the electrolytic sterilizer 52 and the heater 60 in the cold water discharge mode. The water purifier may turn on or off the pump 80 'in the purified water discharge mode. The water purifier can control the circulation and water supply control valve 130 in a non-circulating mode, and control the circulation and water purification valve 132 in a non-bypass mode in the water discharge mode, and the drain valve 94 'in a non-drain mode. Can be controlled by

 When the user inputs the cold water discharge, the water inside the cold water tank 20 passes through the cold water discharge passages 23 and 24 and the cold water valve 26 and is discharged to the outside. At this time, the water in the reservoir 12 flows to the cold water tank 20 as the water in the cold water tank 20 flows to the outside, the water level of the reservoir 12 is the water of the reservoir 12 to the cold water tank 20 Lower as much as it floats. The water purifier, as in the case of cold water discharge, when the water level sensor 18 detects the water level of the reservoir 12, and closes after the water supply valve 6 is opened as in the purified water discharge, it cleans and supplies new water. .

The water purifier may open the hot water valve 36 in the hot water discharge mode, and the hot water heater 33 may be turned on or off. The water purifier may drive or stop the cooling device 22 in the hot water discharge mode, and may close the cold water valve 26. The water purifier may close the water purifying valve 16 in the hot water discharge mode. The water purifier may turn off the electrolytic sterilizer 52 and the heater 60 in the hot water extraction mode. The water purifier may turn on or off the pump 80 'in the hot water discharge mode. The water purifier can control the circulation and water supply control valve 130 in a non-circulating mode in the hot water discharge mode, and also control the circulation and water purification control valve 132 in a non-bypass mode, and the drain valve 94 'in a non-drain mode. Can be controlled by

 When the user inputs the hot water outlet, the water inside the hot water tank 30 passes through the hot water outlet passages 34 and 35 and the hot water valve 36 and is discharged to the outside. At this time, the water in the reservoir 12 flows to the hot water tank 30 as the water in the hot water tank 30 flows to the outside, the water level of the reservoir 12 is the water of the reservoir 12 to the hot water tank 30 Lower as much as it floats. The water purifier is closed when the water level sensor 18 detects the water level of the reservoir 12, and when the water supply valve 6 is opened and closed, as in the case of the hot water discharge and the cold water discharge. Water is purified and watered.

Hereinafter, the drainage mode of a water purifier is demonstrated.

The water purifier may close the purified water valve 16, the cold water valve 26, and the hot water valve 36 in the drainage mode, and may turn on or off the cooling device 22 and the hot water heater 33. The water purifier may turn off the electrolytic sterilizer 52, the heater 60, and the pump 80 in the drainage mode. The water purifier may control the drain valve 94 'in the drain mode in the drain mode.

As the water purifier is shown in FIG. 10 in the drainage mode, the water inside the cold water tank 20 is drained to a part of the circulating sterilization flow path 120 and then drained to the drainage flow paths 92 'and 92 ". 12) the water in the cold water tank 20 flows to the cold water tank 20 as the water flows out to the outside, and then flows to the outside through a portion of the circulating sterilization flow path 120 and the drainage flow paths 92 ′ and 92 ″. Drained.

In the water purifier, the water level sensor 18 detects the water tank of the reservoir 12 in the drainage mode, and the drainage mode may be performed until all of the water in the reservoir 12 is drained, and only a portion of the water in the reservoir 12 is discharged. It is possible for the drainage mode to be carried out until draining.

Hereinafter, the water supply mode of the water purifier will be described.

The water purifier may close the water purifying valve 16, the cold water valve 26, and the hot water valve 36 in the water supply mode, and turn on or off the cooling device 22 and the hot water heater 33. The water purifier may turn off the electrolytic sterilizer 52 and the heater 60 in the water supply mode. The water purifier may control the drain valve 94 'in the non-drain mode in the water supply mode. The water purifier may control the circulation and water supply control valve 130 in a non-circulating mode and also control the circulation and water control valve 132 in a bypass mode in the water supply mode. The water purifier may have the pump 80 turned on or off in the feed mode.

In the water supply mode, as shown in FIG. 11, after the water in the mature water supply flow passage 5 passes through one of the plurality of filters 2, 3, and 4, the filter connection flow passage 7 ′. Passing a portion of (8), it can pass through the electrolytic sterilizer 52 and the heater 60 can be supplied to the water tank (40).

In the water purifier, the water level sensor 18 detects the water tank of the reservoir 12 in the water supply mode, and when the water in the reservoir 12 reaches the full water level, the water supply mode may be completed.

   Hereinafter, the sterilization mode of the water purifier will be described.

The water purifier may close the purified water valve 16, the cold water valve 26, and the hot water valve 36 in the sterilization mode, turn off the cooling device 22, and turn on or off the hot water heater 33. Can be. The water purifier may turn on the electrolytic sterilizer 52, the heater 60, and the pump 80 in the sterilization mode. The water purifier may control the drain valve 94 'in the non-drain mode in the sterilization mode. The water purifier may control the circulation and water supply control valve 130 in the circulation mode in the sterilization mode, and control the circulation and water control valve 132 in the bypass mode.

In the water supply mode, as shown in FIG. 12, the water in the cold water tank 20 is electrolyzed by flowing into the electrolytic sterilizer 52, and the water contains hypochlorite ions, which are sterilization components, while passing through the electrolysis. . Water containing hypochlorite ions, which are sterilizing components, is pumped by the pump 80 to flow into the heater 60, heated by the heater 60, and then flows into the reservoir 12 and the cold water tank 20. Water electrolytically sterilizes the reservoir 12 and the cold water tank 20 while circulating the cold water tank 12, the electrolytic sterilizer 52, the pump 80, the heater 60, the reservoir 12, and the cold water tank 20. And high temperature sterilization, the temperature of which is elevated to a high temperature, and the water containing hypochlorite ions as sterilization components can sterilize the water tank 12 and the cold water tank 20 with higher sterilizing power.

As in the first embodiment of the present invention, the water purifier according to the present embodiment has a sterilization stroke including a first drainage mode step, a water supply mode step, a sterilization mode step, a second drainage mode step, a rinsing mode step, and a third drainage mode. Steps may be included and detailed description of the sterilization stroke is omitted.

1: water purification part 2, 3, 4: filter
10: tank access euro 12: reservoir
20: cold water tank 50: water tank sterilizer
52: electrolytic sterilizer 60: heater
70: circulating sterilization oil 80: pump

Claims (20)

A water purification unit for purifying water;
A water tank including a water tank containing water purified by the water purification unit and a cold water tank into which water of the water tank is introduced and cooled;
An electrolytic sterilizer which electrolyzes water to generate sterilization components;
A heater for heating water;
A circulating sterilization flow path through which the water in the tank circulates the electrolytic sterilizer, the heater and the water tank;
A water purifier including a pump installed in the circulating sterilization flow path for circulating water. The method of claim 1,
The electrolytic sterilizer, the heater and the pump is a water purifier that is turned on together in the sterilization mode. The method of claim 1,
The heater is a water purifier installed after the electrolytic sterilizer in the circulating flow direction of the water. The method of claim 3, wherein
The pump is a water purifier installed between the electrolytic sterilizer and the heater in the circulating flow direction of the water. The method of claim 1,
The circulating sterilization oil passage is connected to a water tank inlet channel for guiding the water passing through the water purification unit to the water tank or the water reservoir, and a cold water outlet channel for water extraction of the cold water tank or the other end connected to the cold water tank. . The method of claim 5, wherein
And a check valve installed in the water tank inlet flow passage to prevent water from flowing into the water purification unit when circulating the electrolytic sterilizer, the heater, and the water tank. The method of claim 5, wherein
The circulation sterilization oil passage includes an electrolytic sterilizer flow passage for guiding water to the electrolytic sterilizer, an electrolytic sterilizer flow passage for guiding water passing through the electrolytic sterilizer, and a heater inlet flow passage for guiding water to the heater; ; Water purifier including a heater discharge passage for guiding the water passing through the heater. The method of claim 7, wherein
The pump is a water purifier connected to the electrolytic sterilizer discharge passage and the heater inlet passage. The method of claim 1,
A drain passage connected to the circulation sterilization passage;
And a drain control valve configured to control the water passing through the heater to flow into the cold water tank or to drain the water of the cold water tank to the drain channel. The method of claim 9,
The drain control valve is a three-way valve is installed in the heater discharge passage between the heater and the cold water tank and the drain passage is connected. The method of claim 1,
The water purification unit includes a plurality of filters that are purified while passing water sequentially,
The water purifier is connected to a bypass mechanism for guiding water to be supplied to at least one of the water tank and the sterilization circulation passage after bypassing at least a portion of the plurality of filters. The method of claim 11,
The bypass mechanism includes a bypass feed passage connected to at least one of the water tank and the sterilization circulation passage;
And a bypass control valve configured to control the water passing through any one of the plurality of filters to flow into the bypass feed passage or to one of the plurality of filters. 11. The method of claim 10,
The bypass control valve is a water purifier is a three-way valve is installed in the filter connecting flow path for connecting any one of the plurality of filters and the bypass water supply passage is connected. A water purifying unit including a plurality of filters which are purified while passing water sequentially, and a pump is installed in a filter connecting passage connecting one of the plurality of filters to the other;
A water tank including a water tank containing water purified by the water purification unit and a cold water tank into which water of the water tank is introduced and cooled;
An electrolytic sterilizer which electrolyzes water to generate sterilization components;
A heater for heating water;
And a circulating sterilization passage through which the water in the tank is pumped by the pump and passed through the electrolytic sterilizer and the heater to be received into the tank. 15. The method of claim 14,
The electrolytic sterilizer, the heater and the pump is a water purifier that is turned on together in the sterilization mode. 15. The method of claim 14,
The heater is a water purifier installed after the electrolytic sterilizer in the circulating flow direction of the water. 15. The method of claim 14,
The circulation sterilization oil passage is a cold water discharge passage capable of withdrawing water from the cold water tank, and a water tank discharge passage connecting one of the cold water tanks and the transfer of the pump among the filter connection passages;
An electrolytic sterilizer acquisition passage connecting the electrolytic sterilizer to the after of the pump in the filter connecting passage;
An electrolytic sterilizer discharge passage connecting the electrolytic sterilizer and the heater;
And a water tank inlet channel for guiding water passing through the water purifier to the water tank and a heater water outlet channel for connecting one of the water tanks and the heater. The method of claim 17,
And a circulation and water supply control valve installed in the filter connection flow passage to allow water passing through any one of the plurality of filters to flow into the pump, or to allow water from the tank outlet flow passage to flow into the pump. The method of claim 17,
And a circulating and purified water control valve installed in the filter connecting passage to allow the water passed through the pump to flow to another one of the plurality of filters or to flow into the electrolytic sterilizer inlet. 15. The method of claim 14,
A drain passage connected to the circulation sterilization passage;
And a drain valve for regulating water passing through the drain passage.

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