KR20220141687A - water purifier - Google Patents

Abstract

The present invention relates to a water purifier discharging hot water and purified water, comprising: a housing forming a storage space; a filter arranged in the housing and purifying water supplied from a water supply source outside; a water supply flow path guiding the water supplied from the water supply source towards the filter; a water introduction valve installed on the water supply flow path and controlling the flow of water moving towards the filter; a water discharge nozzle arranged outside the housing and extracting water passing through the filter; a hot water module forming a heating flow path through which the purified water which has passed through the filter passes, and heating the purified water passing through the heating flow path into hot water when discharging the hot water; a hot water flow path guiding the hot water which has passed through the hot water module towards the water discharge nozzle; and a control unit controlling the operation of the water introduction valve and the hot water module. The present invention is able to maintain the temperature condition of the purified water to be satisfactory.

Description

water purifier {water purifier}

The present invention relates to a water purifier capable of providing a user with purified water maintaining a temperature within a certain range.

In general, a water purifier is a device that filters raw water and supplies it to the user, and is a device that allows the user to extract a desired amount of water at a desired temperature according to the user's operation.

In such a water purifier, when a user operates a lever or a button, filtered water may be taken out through a nozzle. In detail, the water purifier is configured such that the valve of the nozzle is opened and filtered water can be taken out while the user operates the lever or the button, and the user operates the lever or the button while checking the amount of water filled in the cup or container. will end

Such a water purifier may be provided as a water purifier itself or may be mounted on a refrigerator or the like.

In Prior Document 1 (Korean Patent Publication No. 2019-0010596), a case having a storage space, a filter provided inside the case to purify water supplied from a water supply source, and the water supplied from the water supply source are A water supply passage for supplying to the filter, a water supply valve provided on the water supply passage to control the flow of water passing through the water supply passage, and a water outlet nozzle provided on the outside of the case and through which water passing through the filter is taken out and an outlet channel for supplying the water that has passed through the filter to the outside of the case, a water outlet valve provided on the outlet channel to control the flow of water passing through the outlet channel, and an operation unit that receives a washing command from a user and a control unit controlling to intermittently open or close at least one of the water supply valve and the water outlet valve when a washing command is input to the operation unit.

In addition, Prior Document 2 (Korean Patent Publication No. 2007-0083008) discloses a direct storage device employing an RO membrane module. The disclosed direct water purification apparatus includes a purified water storage tank in which purified water is temporarily stored, a first connection pipe providing a flow path to supply purified water flowing through a purified water discharge pipe to the purified water storage tank, and a purified water stored in the purified water storage tank to flow into the RO membrane module. A second connection pipe providing a flow path, a booster pump installed on the path of the raw water supply pipe to increase the supply pressure of raw water, and a faucet that detects when the faucet is locked, supplies purified water discharged through the purified water discharge pipe to the purified water storage tank and a controller that controls to supply the stored purified water to the RO membrane module when a predetermined amount of purified water is stored in the purified water storage tank.

In the case of the conventional water purifier as described above, when the purified water is dispensed, after selecting the 'clean water' button and pressing the 'water out' button, the purified water valve is opened, purified water flows through the purified water flow path, and purified water is discharged through the water outlet nozzle .

In addition, in the case of the conventional water purifier as described above, when hot water is dispensed, after selecting the 'hot water' button and pressing the 'dispensing' button, the hot water valve is opened, the hot water heated in the hot water tank flows through the hot water flow path, and the water outlet nozzle Hot water is discharged through

That is, in the case of a conventional water purifier, a hot water passage and an intermediate passage are formed separately, hot water is supplied to the water outlet nozzle through the hot water passage and the hot water valve, and purified water is supplied to the water outlet nozzle through the intermediate passage and the water purification valve.

As described above, a conventional water purifier providing cold water, purified water, and hot water outlet functions separately includes a cold water flow path, an intermediate flow path, and a hot water flow path. This is to distinguish the flow paths of water with different temperatures. As such, it was taken for granted that the flow path is provided according to the temperature of the water being discharged. However, in configuring each flow path, the complexity increases, the space utilization is disadvantageous, and there are problems such as an increase in unit price.

In addition, in the conventional water purifier that provides cold water, purified water, and hot water outlet functions as described above, when purified water is dispensed, raw water passes through a filter and then is discharged immediately.

Therefore, the water outlet temperature of purified water is greatly affected by the ambient temperature. In detail, there is a tendency that the temperature of the purified water outlet decreases in winter and increases in the summer.

In particular, in winter, due to the influence of the ambient temperature, cold purified water is inevitably discharged, and user dissatisfaction may occur due to the cold purified water being discharged.

On the other hand, in summer, due to the influence of the ambient temperature, lukewarm purified water is inevitably discharged, and user dissatisfaction may arise due to the outflow of lukewarm purified water.

Prior Literature 1. Korean Patent Publication No. 2019-0010596 (2019-01-28) Prior Document 2. Korean Patent Publication No. 2007-0083008 (2007-08-17)

The present invention solves the problem that cold water is provided to the user by heating the purified water by checking the water intake temperature at the time of water extraction, and heating the purified water when the water intake temperature is lower than the set reference temperature, regardless of the ambient temperature An object of the present invention is to provide a water purifier from which purified water can be dispensed at all times.

In addition, the present invention solves the problem that lukewarm purified water is provided to the user by mixing purified water and cold water when the ingestion temperature is higher than the set reference temperature by checking the ingestion temperature when purified water is dispensed, and regardless of the ambient temperature , an object of the present invention is to provide a water purifier from which purified water of a set temperature can be dispensed at all times.

In addition, the present invention provides a water purifier capable of reducing material costs due to the provision of a purified water passage and a water purification valve by implementing a flow path to discharge hot water and purified water through a hot water flow passage without providing a separate purified water passage and a water purification valve It is intended to

Another object of the present invention is to provide a water purifier capable of reducing the size of the water purifier by eliminating the configuration of the purified water passage and the water purifying valve, thereby increasing the use of space inside the water purifier.

In addition, when purified water is dispensed after hot water is dispensed, the residual water is discharged after hot water is dispensed so that the temperature of the dispensed purified water does not increase due to the residual hot water. Its purpose is to provide

In addition, when purified water is dispensed after hot water is dispensed, the temperature of the water dispensed through the cold water is lowered so that the temperature of the purified water dispensed does not increase due to the residual hot water. Its purpose is to provide

In order to achieve the above object, a housing forming a storage space, a filter provided inside the housing to purify water supplied from an external water supply source, and water supplying water supplied from the water supply source to the filter side A flow path, a water inlet valve installed in the water supply flow path to control the flow of water flowing toward the filter, a water outlet nozzle provided on the outside of the housing, through which water passing through the filter is taken out, and the filter A hot water module that forms a heating flow path through which purified water passes, and heats the purified water passing through the heating flow path to hot water when hot water is discharged; And it provides a water purifier comprising a control unit for controlling the operation of the hot water module.

In addition, when purified water is dispensed, purified water passing through the filter flows toward the outlet nozzle through the hot water module and the hot water flow path, and the controller may selectively operate the hot water module.

In addition, the controller may turn on or off the hot water module when purified water is dispensed, and turn on the hot water module when hot water is dispensed.

In addition, it may further include a first temperature sensor for measuring the temperature of the water flowing to the hot water module.

In addition, the control unit receives the temperature information of the water measured by the first temperature sensor, and turns on the hot water module when the temperature of the water input from the first temperature sensor is lower than a preset first reference temperature when purified water is dispensed. (on) can be turned on.

In addition, it may further include a second temperature sensor for detecting the temperature of the water discharged from the hot water module and flowing toward the water outlet nozzle.

In addition, the control unit receives the temperature information of the water measured by the second temperature sensor, and when the purified water is dispensed, when the temperature of the water input from the second temperature sensor is lower than the first preset reference temperature, the output of the hot water module can be controlled to increase.

In addition, the control unit receives the temperature information of the water measured by the second temperature sensor, and when the purified water is dispensed, if the temperature of the water input from the second temperature sensor is equal to or higher than a preset first reference temperature, the output of the hot water module is It can be controlled to be maintained or decreased.

In addition, the controller may control the output of the hot water module to be maintained when the temperature of the water input from the second temperature sensor is equal to or greater than a preset first reference temperature and is less than a preset second reference temperature.

In addition, when the temperature of the water input from the second temperature sensor is equal to or greater than a preset second reference temperature, the controller may control the output of the hot water module to decrease.

In addition, the control unit may receive the temperature information of the water measured by the temperature sensor, and when purified water is dispensed, if the input water temperature is equal to or greater than a preset first reference temperature, the hot water module may be turned off.

The water outlet may further include a water outlet passage having one side connected to the hot water passage and the other end connected to the water outlet nozzle, and a water outlet valve for controlling the flow of water flowing toward the water outlet nozzle may be installed in the water outlet passage.

In addition, the water outlet valve is provided as a three-way valve, and a drain passage is connected to the water outlet valve, and the water outlet valve allows the inflowed water to flow toward the water outlet nozzle or to the drain passage. can

In addition, when hot water is dispensed, the water outlet valve is opened toward the water outlet nozzle, and when the hot water outlet is finished, the water outlet valve is opened toward the drain passage to drain residual water.

In addition, one side is connected to the outlet side of the filter, the other side is connected to the inlet side of the hot water module, the intermediate flow path for guiding the water passing through the filter to the hot water module side, one side is branched from the intermediate flow path, A cold water flow passage in which the other side joins the water outlet passage connected to the water outlet nozzle, the cold water module may further include a cold water module installed in the cold water passage to cool the purified water passing through the cold water passage with cold water.

In addition, a cold and hot water valve is installed at a branch point of the cold water passage in the intermediate passage, and when hot water is released or purified water is discharged, the cold and hot water valve is opened toward the hot water module, and when cold water is discharged, the cold and hot water valve is opened toward the cold water passage can be

In addition, if purified water is dispensed within a first preset time after hot water is dispensed, the cold/hot water valve may be opened toward the hot water module and the cold water flow path.

The present invention has the advantage that, when purified water is discharged, the obtained temperature is checked, and when the obtained temperature is lower than the set reference temperature, the purified water is heated, so that the purified water of the set temperature can be discharged instead of the cold purified water.

In addition, the present invention, when purified water is dispensed, check the availability temperature, and when the acquisition temperature is higher than the set reference temperature, mix purified water and cold water, instead of lukewarm purified water, there is an advantage that purified water of a set temperature can be dispensed.

In addition, the present invention has an advantage in that it is possible to reduce the material cost due to the provision of the purified water flow path and the purified water valve by implementing the hot water and purified water to be discharged through the hot water flow path without providing a separate purified water flow path and water purification valve.

In addition, since the configuration of the purified water passage and the purified water valve can be eliminated, the space utilization inside the water purifier can be increased, and the water purifier can be miniaturized.

In addition, since the configuration of the purified water passage and the purified water valve can be deleted, there is an advantage in that maintenance costs such as periodic pipe replacement costs can be reduced.

In addition, when purified water is dispensed after hot water is dispensed, the residual water is discharged after hot water is dispensed so that the temperature of purified water dispensed due to residual hot water does not increase, so that the temperature condition of the dispensed purified water can be maintained in a satisfactory state. have.

In addition, when purified water is dispensed after hot water is dispensed, the temperature of the dispensed purified water can be maintained in a satisfactory state by lowering the temperature of the water dispensed through the cold water so that the temperature of the dispensed purified water does not increase due to the residual hot water. There is this.

1 is a perspective view of a water purifier according to an embodiment of the present invention.
2 is a perspective view showing a changed position of the water outlet nozzle of the water purifier according to an embodiment of the present invention.
3 is an exploded perspective view of a water purifier according to an embodiment of the present invention.
FIG. 4 is an exploded perspective view showing a partial region of FIG. 3 .
5 is a water pipe diagram of a water purifier according to an embodiment of the present invention.
6 is a block diagram showing the configuration of a water purifier according to an embodiment of the present invention.
7 to 8 are control flowcharts illustrating a process in which purified water is discharged from the water purifier according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the embodiments presented below, and those skilled in the art who understand the spirit of the present invention may change other embodiments included within the scope of the same spirit by adding, changing, deleting, and adding components. It will be easy to implement, but this will also be included within the scope of the present invention.

The drawings attached to the following embodiments are embodiments of the same inventive idea, but within the scope that the inventive idea is not damaged, in order to be easily understood, the expression of minute parts may be expressed differently for each drawing. and a specific part may not be indicated according to the drawings, or may be exaggeratedly expressed according to the drawings.

<Water Purifier>

1 is a perspective view of a water purifier according to an embodiment of the present invention, and FIG. 2 is a perspective view showing a state in which a position of a water outlet nozzle of the water purifier according to an embodiment of the present invention is changed. It is an exploded perspective view of a water purifier according to an embodiment, and FIG. 4 is an exploded perspective view showing a partial region of FIG. 3 .

1 to 2 , the water purifier according to an embodiment of the present invention includes a water purifier body 100 , disposed inside the water purifier body 100 , and rotatably mounted on the water purifier body 100 . a rotator 200 that becomes a rotator 200, at least a portion of the operation unit 300 disposed above the rotator 200, and at least a portion of the rotator 200 is fixed to the rotator 200, and protrudes toward the front of the water purifier body 100, A fixed cover 410 in which at least a portion of the operation unit 300 is disposed on the upper end, a lifting cover 420 that moves up and down while being supported in contact with the fixed cover 410, and a water outlet nozzle mounted on the lower end of the lifting cover 420 It may include a water extraction module 400 made of 430 .

According to the present invention, the water extraction module 400 may rotate in the left and right directions with respect to the water purifier body 100 by the rotator 200 . In addition, the lifting cover 420 and the water outlet nozzle 430 may be raised and lowered based on the fixed cover 410 fixed to the rotator 200 .

Accordingly, the position of the water outlet nozzle 430 may be varied in the left and right directions, and the position of the water outlet nozzle 430 may also be varied in the vertical direction.

The rotator 200 includes a circular rotator body 210 having a hollow, an upper disk 220 fixed to an upper portion of the rotator body 210 or a lower disk 230 fixed to a lower portion of the rotator body 210 . ) may be included.

The rotator body 210 and the upper disk 220 or the lower disk 230 may be combined into one module by assembling or the like.

In addition, the manipulation unit 300 may be rotatably disposed on the upper surface of the water purifier body 100 . The manipulation unit 300 may be disposed above the rotator 200 .

In addition, the manipulation unit 300 may be disposed on the upper end of the water outlet module 400 protruding forward of the water purifier body 100 . In detail, the manipulation unit 300 may be disposed on the upper end of the fixed cover 410 .

Accordingly, when the water extraction module 400 rotates, the rotator 200 and the operation unit 300 connected to the water extraction module 400 rotate at the same time.

At the lower end of the elevating cover 420, a grip portion 425 of a shape protruding outward or concave inward may be formed. With the configuration of the grip part 425 , the user can raise or lower the lifting cover 420 by holding the lower end of the lifting cover 420 without slipping.

Meanwhile, the water purifier body 100 includes a housing 110 and a filter 120 .

The outer shape of the water purifier 10 may be formed by the housing 110 . The housing 110 includes a front cover 111 forming a front exterior, a rear cover 112 forming a rear exterior, a base 113 forming a lower surface, a top cover 114 forming an upper surface, and left and right sides. It is composed of side panels 115 that form both sides. The front cover 111 and the rear cover 112 , the base 113 , the top cover 114 , and the pair of side panels 115 may be assembled with each other to form the exterior of the water purifier 10 .

At this time, the front or rear ends of the base 113 and the top cover 114 may be formed to be rounded, and the front cover 111 or the rear cover 112 may be formed to be rounded with the base 113 and the top cover ( 114) may be formed to be convex forward or rearward, respectively, to have a curvature corresponding to the front end or rear end.

A filter 120 for purifying and discharging raw water introduced from the widow is provided inside the housing 110 .

On the front surface of the water purifier body 100 , the water outlet module 400 is disposed to protrude forward, and purified water passes through the filter through the water outlet nozzle 430 formed to protrude downward at the lower end of the water outlet module 400 . can be taken out.

In addition, purified water passing through the filter may be cooled or heated and then supplied to the water outlet nozzle 430 in the form of cold water or hot water.

Meanwhile, the front cover 111 may include an upper cover 111a and a lower cover 111b.

For reference, in a state in which the water extraction module 400 rotates to both sides, a container such as a cup can be stably supported by the flat side panel 115 .

The water extraction module 400 is configured to rotate together with the rotator 200 . Accordingly, the user can rotate the water outlet module 400 at a desired angle according to the installation state of the water purifier 10 or the installation environment.

In addition, the manipulation unit 300 disposed above the rotator 200 or disposed above the fixed cover 210 has a structure that rotates together with the water outlet module 400 and the rotator 200 .

In addition, the water extraction module 400 has a structure that elevates while being fixed to the outside of the rotator 200 .

Referring to FIGS. 3 to 4 , a filter 120 for water purification and a filter bracket 130 to which a plurality of valves are mounted are provided inside the housing 110 .

The filter bracket 130 may include a bottom portion 131 coupled to the base 113 and a filter receiving portion 132 in which the filter 120 is accommodated.

The bottom portion 131 is formed to correspond to the shape of the tip of the base 113 , and is coupled to the base 113 . The mounting position of the filter bracket 130 may be fixed by the coupling of the bottom part 131 , and the shape of the bottom surface of the filter accommodating part 132 may be formed.

The filter accommodating part 132 is formed to extend in the vertical direction, and forms a recessed space from the front (left in the drawing) to the rear (right in the drawing) so that the filter 120 can be accommodated. A plurality of filters 120 may be mounted on the filter receiving part 132 . The filter 120 is for purification of supplied raw water (tap water) and may be configured to combine filters having various functions.

In addition, the filter receiving part 132 may further include a filter socket 134 to which the filter 120 is mounted, and a pipe through which purified water flows is provided in the filter socket 134 , The pipe may be connected to a plurality of valves (not shown). Accordingly, the raw water passes through the filter 120 in turn and then can be directed to a valve (not shown) for water supply.

A plurality of valves (not shown) may be provided on the rear surface (right side of the drawing) of the filter accommodating part 132 , and the valves (not shown) convert the purified water passing through the filter 120 into cold water for generating cold water. It may be supplied to the module 150 or the hot water module 170 for generating hot water. In addition, purified water may be directly supplied to the water outlet module 400 .

For example, the cold water module 150 may include a thermoelectric element to generate cold water.

As another example, the cold water module 150 may include a compressor 151 to generate cold water.

The cold water module 150 may be understood as a configuration including a cooling tank 151 , a compressor 151 , a condenser 152 , a cooling fan 153 , and the like.

A compressor 151 and a condenser 152 may be provided on the upper surface of the base 113 . In addition, a cooling fan 153 is provided between the compressor 151 and the condenser 152 to enable cooling of the compressor 151 and the condenser 152 . The compressor 151 may be an inverter type compressor capable of adjusting the cooling capacity by varying the frequency. Accordingly, the cooling of the purified water can be efficiently performed, thereby reducing power consumption.

In addition, the condenser 152 may be located at the rear of the base 113 , and may be located at a position corresponding to the discharge port 112a formed in the rear cover 112 . The condenser 152 may be formed by bending a flat tube type refrigerant tube a plurality of times in order to efficiently use space and improve heat exchange efficiency at the same time, and is configured to be accommodated in the condenser bracket 154 .

A condenser mounting part 155 to which the condenser 152 is fixed and a tank mounting part 156 to which a cooling tank 151 for making cold water can be mounted are formed in the condenser bracket 154 . The condenser mounting part 155 forms a space having a shape corresponding to the overall shape of the condenser 152 to accommodate the condenser 152 . In addition, the condenser mounting part 155 is formed such that portions facing the cooling fan 153 and the discharge port 112a are opened, respectively, so that effective cooling of the condenser 152 is possible.

In addition, the tank mounting part 156 is formed above the condenser bracket 154 , that is, above the condenser mounting part 155 . The lower end of the cooling tank 151 is inserted into the tank mounting unit 156 so that the tank mounting unit 156 fixes the cooling tank 151 .

The cooling tank 151 is for making cold water by cooling the purified water, and the cooling water for heat exchange with the incoming purified water is filled. In addition, an evaporator for cooling the cooling water may be accommodated in the cooling tank 151 . In addition, the purified water may be cooled by allowing the purified water to pass through the cooling tank.

A support plate 135 extending toward the cooling tank 151 is further disposed on one side of the filter bracket 130 . The support plate 135 is provided above the compressor 151 and extends from the filter bracket 130 to the condenser bracket 154 to provide a space in which the heating and control module 160 is mounted.

The heating and control module 160 may include a hot water module 170 for making hot water and a controller 180 for controlling the overall operation of the water purifier 10 . The hot water module 170 and the control unit 180 may be coupled to each other to form a single module, and may be mounted on the support plate 135 in a coupled state.

The hot water module 170 is configured to heat purified water.

For example, the hot water module 170 is configured to heat water in an induction heating (IH) method. The hot water module 170 can heat water at an instant and fast speed when hot water is taken out, and can heat purified water to a desired temperature by controlling the output of a magnetic field and provide it to the user. Therefore, it is possible to extract hot water of a desired temperature according to a user's operation.

As another example, the hot water module 170 may include a thermoelectric element to heat water.

The control unit 180 is for controlling the operation of the water purifier 10 , the cold water module 150 including the compressor 151 , the cooling fan 153 , various valves and sensors, and the hot water module 170 . ) and so on. The controller 180 may be modularly configured by a combination of PCBs divided into a plurality of parts for each function.

Referring back to FIGS. 1 to 4 , a tray 500 is disposed at the lower end of the front cover 111 to protrude forward. In addition, the tray 500 may be positioned vertically below the water extraction module 400 . In addition, the tray 500 may be rotated by a user's manipulation, and may be separated from the base 113 . The tray 500 may form a grill vertically below the water outlet nozzle 430 so that water falling from the water outlet nozzle 430 can be stored.

The tray 500 may be rotatably disposed on the base 113 or the front cover 111 .

Accordingly, when the water extraction module 400 rotates, the tray 500 may also rotate along the water extraction module 400 , and the tray 500 may be positioned vertically below the water extraction module 400 .

The water extraction module 400 , the operation unit 300 , the rotator 300 , and the tray 900 may rotate based on the same rotational center.

On the other hand, the operation unit 300 is provided with a touch panel, a capacity button for selecting the water outlet capacity, a hot water button for selecting hot water, and further selecting the temperature of the hot water to be dispensed, a water purifying button for selecting purified water, and cold water for selecting It may include a cold water button, a continuous button for selecting continuous water extraction, and a self-care button for inputting a sterilization command and/or a washing command.

Also, the controller 180 may include an inverter. The inverter may control the amount of heating by controlling the amount of current applied to the heating source of the hot water module 170 . That is, the output of the hot water module 170 may be adjusted by the inverter.

When the amount of heating is adjusted in this way, the water may be heated to a temperature desired by the user.

Also, the controller 180 may further include a noise filter. The noise filter serves to remove noise from a signal including noise generated by a magnetic field generated by a current applied to the hot water module 170 .

The noise filter may control noise in control signals output from the controller 180 and applied to various valves.

In addition, the controller 180 may include a timer for measuring the elapsed time after the hot water is dispensed.

<Euro Structure>

5 is a water pipe diagram of a water purifier according to an embodiment of the present invention. And, Figure 6 is a block diagram showing the configuration of the water purifier according to an embodiment of the present invention.

Referring to FIG. 5 , the water purifier according to the present invention discharges hot water and purified water, but the hot water and purified water are discharged through one flow path.

First, the water supplied from the water supply source is guided to the filter 120 side through the water supply passage 710 .

And, the purified water that has passed through the filter 120 flows through the intermediate flow path 720 .

The intermediate flow path 720 has one side connected to the outlet side of the filter 120, and the other side connected to the inlet side of the hot water module 170, so that the water passing through the filter 120 is transferred to the hot water module ( 170) to the side.

In addition, purified water or hot water passing through the hot water module 170 is supplied to the water outlet nozzle 430 through the hot water flow path 740 .

The hot water passage 740 is connected to the water outlet nozzle 430 through the water outlet passage 760 . Accordingly, the water passing through the hot water module 170 and the hot water flow path 740 passes through the water outlet flow path 760 and then is discharged to the water outlet nozzle 430 .

At this time, when power is supplied to the hot water module 170 and the purified water is heated in the hot water module 170 , the hot water is discharged through the water outlet nozzle 430 .

In addition, when the power to the hot water module 170 is cut off, the purified water that has passed through the hot water module 170 is not heated and is discharged to the water outlet nozzle 430 in the state of purified water.

That is, in the case of the present invention, hot water and purified water are discharged through one flow path.

In the case of hot water and purified water, both pass through the water supply flow path 710, the filter 120, the intermediate flow path 720, the hot water module 170, the hot water flow path 740, and the water outlet flow path 760, and the water outlet nozzle 430. is discharged with

The difference is whether the hot water module 170 operates. When purified water is dispensed, the controller 180 switches the hot water module 170 to an off state so that the hot water module 170 does not operate, and the purified water that has passed through the hot water module 170 is converted to a purified water flow path ( 760). On the other hand, when hot water is dispensed, the controller 180 switches the hot water module 170 to an on state, the hot water module 170 operates, and the purified water passing through the hot water module 170 is heated with hot water. .

The hot water module 170 includes a hot water tank. In addition, a heating flow path 171 through which the purified water passing through the filter 120 passes is formed in the hot water tank, and the purified water passing through the heating flow path 171 when hot water is discharged is heated with hot water. On the other hand, the purified water that has passed through the heating passage 171 when purified water is discharged maintains the purified water state without a change in temperature.

Referring to FIG. 5 , it includes a hot water flow path 740 and a water outlet flow path 760 for guiding the purified water or hot water passing through the hot water module 170 toward the water outlet nozzle 430 . That is, purified water or hot water discharged from the hot water module 170 is discharged to the water outlet nozzle 430 through the hot water passage 740 and the water outlet passage 760 .

The controller 180 controls the operation of the hot water module 170 .

When purified water is dispensed, the controller 180 turns off the heating source of the hot water module 170 , and the purified water discharged from the hot water module 170 passes through the hot water flow path 740 and the water outlet flow path 760 . Water is discharged through the water outlet nozzle 430 . That is, when purified water is dispensed, the heating source of the hot water module 170 is turned off, and when purified water passes through the heating flow path 171 of the hot water module 170, it is not heated and can be discharged in a purified state. . In addition, purified water may be supplied to the water outlet nozzle 430 through the hot water passage 740 and the water outlet passage 760 .

In addition, when hot water is dispensed, the controller 180 turns on the heating source of the hot water module 170 , and the hot water discharged from the hot water module 170 is a hot water channel 740 and a water outlet channel 760 . It is discharged to the water outlet nozzle 430 through That is, when the heating source of the hot water module 170 is turned on, the purified water is heated when passing through the heating passage 171 of the hot water module 170 and discharged in the state of hot water. In addition, the hot water discharged from the hot water module 170 may be supplied to the water outlet nozzle 430 through the hot water passage 740 and the water outlet passage 760 .

Again, referring to FIGS. 5 and 6 , in the water purifier according to the present invention, a flow rate control valve 640 may be installed in at least one of the water supply flow path 710 , the intermediate flow path 720 , and the hot water flow path 740 . have. The flow rate control valve 640 may control the flow rate of water flowing into the hot water module 170 , flowing out of the hot water module 170 , or passing through the hot water module 170 .

For example, the flow rate control valve 640 may control the flow rate of water passing through the hot water module 170 to be low.

The controller 180 is connected to the flow control valve 640 to control the flow control valve 640 . In detail, the controller 180 may open or block the flow control valve 640 . In addition, the control unit 180 may control the degree of opening of the flow rate control valve 640 , and consequently control the flow rate of water passing through the hot water module 170 .

In addition, a temperature sensor 680 for detecting the temperature of water may be installed in the flow control valve 640 .

The temperature sensor 680 may be installed integrally with the flow control valve 640 .

For reference, the temperature sensor 680 may be installed in at least one of various water supply passages 710 , intermediate passages 720 , hot water passages 740 , and outlet water passages 760 . In addition, the temperature sensor 680 may be installed in the hot water module 170 or the water inlet valve 630 or the like, or may be installed in the water outlet valve 670 to be described later.

Also, the controller 180 may be connected to the temperature sensor 680 to receive the temperature information of the water sensed by the temperature sensor 680 . And by utilizing the received temperature information, it is possible to control the output of the hot water module 170.

In addition, a water inlet valve 630 may be installed in the water supply passage 710 .

The water inlet valve 630 may control the flow of water flowing from the water supply passage 710 to the filter 120 side.

The water supply passage 710 is a first water supply passage 711 for guiding water toward the water inlet valve 630, based on the water inlet valve 630, and the water discharged from the water inlet valve 630 through the filter 120 ) may include a second water supply passage 712 for guiding to the side.

For example, the water introduced into the water inlet valve 630 through the first water supply passage 711 may be discharged to the second water supply passage 712 and then introduced into the filter 120 .

In general, in the case of purified water, after passing through the filter 120 , it is supplied to the water outlet nozzle 430 through a flow path. Therefore, there is no need to adjust the flow rate of water passing through the flow path, the larger the flow rate, the better.

However, in the case of hot water, after passing through the filter 120 , it is heated with hot water, and then supplied to the water outlet nozzle 430 . Therefore, in order to increase the temperature of hot water, it is necessary to adjust the flow rate of water flowing into the hot water module 170 to be lower than that of purified water.

In the present invention, when hot water is dispensed, the controller 180 may control the degree of opening of the flow rate control valve 640 to be lower than that of purified water.

As described above, when the opening degree of the flow control valve 640 is lowered, as a result, the flow rate passing through the hot water module 170 is adjusted to be low, and accordingly, the hot water temperature is increased, so that the hot water condition can be satisfied.

Meanwhile, when purified water is dispensed, the controller 180 may control the opening degree of the flow control valve 640 to be increased.

For example, when purified water is dispensed, the controller 180 may control the flow rate control valve 640 to be opened to the maximum.

Accordingly, a situation in which the purified water flow rate is lowered is prevented, and the purified water flow rate condition can be satisfied.

That is, in the case of the present invention, by controlling the degree of opening of the flow control valve 640, the opening amount of the flow control valve 640 is maximized to increase the opening amount of the flow control valve 640 when purified water is discharged, so that the purified water flow is not reduced, and when hot water is discharged, the flow rate By reducing the opening amount of the control valve 640 to lower the flow rate, it is possible to satisfy the temperature condition of the hot water.

Meanwhile, as described above, the purified water discharged from the filter 120 flows toward the hot water module 170 through the intermediate flow path 720 .

Then, the water introduced into the hot water module 170 is heated and discharged in the state of hot water, or is discharged in the state of purified water without being heated to flow the hot water flow path 740 .

The hot water or purified water flowing through the hot water passage 740 flows through the water outlet passage 760 and then is supplied to the outside of the water purifier through the water outlet nozzle 430 .

One side of the water outlet passage 760 is connected to the hot water passage 740 and the other end is connected to the water outlet nozzle 430 .

In addition, a water outlet valve 670 for controlling the flow of water flowing toward the water outlet nozzle 430 may be installed in the water outlet flow path 760 .

The controller 180 may control the operation of the water outlet valve 670 .

In detail, the controller 180 may control the water outlet valve 670 to be opened when purified water, hot water, or cold water is dispensed, and control the water outlet valve 670 to be blocked in a standby state where no water dispensed. .

On the other hand, after the hot water is dispensed, the hot water module 170 is in a heated state, and the hot water flow path 740 and the hot water module 170 and the hot water outlet channel 760 are also filled with hot water.

In this situation, when the user dispenses purified water, a problem occurs in that the hot water in the hot water flow path 740 or the hot water module 170 is discharged through the water outlet nozzle 430 before the purified water is dispensed.

Therefore, after hot water is dispensed, before purified water is dispensed, it is necessary to drain the hot water (residual water) remaining in the hot water flow path 740 , the hot water module 170 , and the water outlet flow path 760 .

To this end, the water purifier of the present invention includes a drain passage 770 .

In addition, the water outlet valve 670 is provided as a three-way valve, and a drain flow path 770 may be connected to the water outlet valve 670 .

In addition, the water introduced into the water outlet valve 670 may flow toward the water outlet nozzle 430 and may flow into the drain passage 770 .

The water outlet valve 670 may have one inlet and two outlets. In addition, the inlet of the water outlet valve 670 is connected to the water outlet passage 760 extending toward the hot water passage 740 . Then, one of the two outlets is connected again to the water outlet passage 760 extending toward the water outlet nozzle 430 , and the other one is connected to the drain passage 770 .

The controller 180 may open and close the inlet of the water outlet valve 670 and may open/close the outlet of the water outlet valve 670 . The control unit 180 may select and open any one of the outlets of the water outlet valve 670 and block the other one. The controller 180 may open all outlets of the water outlet valve 670 and may block all outlets of the water outlet valve 670 .

Accordingly, the water introduced into the water outlet valve 670 may be discharged through the water outlet passage 760 extending toward the water outlet nozzle 430 and discharged to the water outlet nozzle 430 or discharged to the drain passage 770 . .

For example, when hot water is dispensed, the water outlet valve 670 may be opened to discharge water through the water outlet passage 760 extending toward the water outlet nozzle 430 .

As another example, when the hot water outlet is finished, the outlet connected to the drain channel 770 of the outlet valve 670 is opened, and the residual water in the hot water channel 740 , the outlet channel 760 or the hot water module 170 is drained. can be

As described above, when the drain proceeds after the hot water is dispensed, the hot water flow path 740 , the outlet water flow path 760 , or the hot water module 170 is filled with purified water or emptied.

Accordingly, it is possible to prevent a problem in which the temperature of purified water increases due to the high-temperature residual water when purified water is dispensed after hot water is dispensed.

If, after hot water is dispensed, if purified water is dispensed in a state in which the drain has not proceeded, even if the hot water module 170 is turned off, the hot water flow path 740 , the outlet flow path 760 , or the hot water module 170 has a high temperature. Since the residual water of the remaining water is in the state, there is a problem that high-temperature water is discharged through the water outlet nozzle 430 .

In the case of the present invention, when the hot water is dispensed, the drain may be performed regardless of whether purified water is dispensed.

That is, when hot water is dispensed, the hot water module 170 operates, and the outlet of the water outlet valve 670 on the water outlet nozzle 430 side is opened.

And, when the hot water outlet is finished, the hot water module 170 stops operating, and the outlet of the outlet valve 670 on the drain channel 770 side is opened, so that the hot water in the hot water channel 740 or the hot water module 170 is drained. Through the flow path 770, it is drained.

And, when the predetermined drain time has elapsed, the outlet of the water outlet valve 670 on the drain passage 770 side is blocked.

In addition, in the case of the present invention, when hot water is dispensed and purified water is dispensed, the elapsed time is checked after hot water is dispensed, and the drain may be selectively performed according to the elapsed time.

In addition, in the case of the present invention, when the hot water outlet is terminated and purified water is dispensed, the temperature of the residual water of the hot water flow path 740 or the water outlet flow path 760 or the hot water module 170 or the water outlet valve 670 is checked, and the checked Depending on the temperature, the drain may be selectively performed.

Again, referring to FIGS. 5 to 6 , the water purifier according to the present invention may have a cold water function.

To this end, one side is branched from the intermediate flow path 720 , and the other side is installed in the cold water flow path 750 and the cold water flow path 750 where the other side joins the outlet water flow path 760 , and the cold water flow path 750 is separated. It may further include a cold water module 150 for cooling the purified water passing through the cold water.

In addition, in the intermediate flow path 720 , a cold/hot water valve 660 may be installed at a branch point of the cold water flow path 750 .

The controller 180 controls the operation of the cold/hot water valve 660 .

For example, when hot water is released or purified water is dispensed, the controller 180 may control the cold/hot water valve 660 to be opened toward the hot water module 170 .

As another example, when cold water is dispensed, the controller 180 may control the cold/hot water valve 660 to be opened toward the cold water flow path 750 .

The cold/hot water valve 660 may have one inlet and two outlets. In addition, the inlet of the cold/hot water valve 660 is connected to the intermediate flow passage 720 extending toward the filter 120 . And, one of the two outlets is connected again to the intermediate flow passage 720 extending toward the hot water module 170 , and the other one is connected to the cold water passage 750 .

The controller 180 may open and close the inlet of the cold/hot water valve 660 and may open/close the outlet of the cold/hot water valve 660 . The controller 180 may select and open any one of the outlets of the cold/hot water valve 660 and block the other one. The controller 180 may open all outlets of the hot/cold water valve 660 and may block all outlets of the water outlet valve 670 .

Accordingly, the water introduced into the cold and hot water valve 660 may be discharged to the intermediate flow path 720 extending toward the hot water module 170 and supplied to the hot water module 170 or discharged to the cold water flow path 750 . .

As a modified example, after the hot water is dispensed, it is in a heated state, and the hot water flow path 740 , the hot water module 170 , and the hot water flow path 760 are also filled with hot water.

In this situation, when the user dispenses purified water, a problem occurs in that the hot water in the hot water flow path 740 or the hot water module 170 is discharged through the water outlet nozzle 430 before the purified water is dispensed.

The controller 180 may control the temperature of the water discharged to the water outlet nozzle 430 to be low through the cold water.

In this embodiment, when purified water is dispensed within a preset reference time after hot water is dispensed, the controller 180 opens the outlet on the side of the intermediate flow path 720 in which the cold/hot water valve 660 is connected to the hot water module 170 . and the cold water flow path 750 side outlet is also controlled to be opened.

Here, the 'reference time' may be set in various ways. For example, the 'reference time' may be set to 60 minutes.

In addition, after hot water is dispensed, before the reference time elapses, when purified water is dispensed, the controller 180 simultaneously opens both outlets of the cold and hot water valve 660 , but the outlet at the cold water flow path 750 side is closed for the first time. After being opened, it is controlled to be blocked, and the outlet of the intermediate flow path 720 connected to the hot water module 170 is controlled to be opened for a second time longer than the first time.

Here, the 'first time' and the 'second time' may be set in various ways. For example, the 'first time' may be set to 3 seconds.

In addition, the water discharged through the cold water passage 750 and the hot water passage 740 may be discharged through the water outlet nozzle 430 after being merged in the water outlet passage 760 .

In addition, in the case of the present invention, when hot water is dispensed and purified water is dispensed, an elapsed time is checked after hot water is dispensed, and a part of cold water can be selectively merged with the remaining water according to the elapsed time.

In addition, in the case of the present invention, when the hot water outlet is terminated and purified water is dispensed, the temperature of the residual water of the hot water flow path 740 or the water outlet flow path 760 or the hot water module 170 or the water outlet valve 670 is checked, and the checked Depending on the temperature, a portion of the chilled water may optionally be joined to the residual water.

Accordingly, when purified water is dispensed through the hot water flow path, the problem of discharging hot water or lukewarm water at the initial stage when purified water is dispensed due to residual hot water can be solved.

Again, referring to FIG. 5 , the water supply passage 710 has a pressure reducing valve 610 for controlling the water pressure of water introduced from the water supply source, or a flow rate sensor 620 for checking the flow rate of water passing through the water supply passage 710 . ), at least one of which may be installed.

For example, in the first water supply passage 711 , a pressure reducing valve 610 and a flow rate sensor 620 may be sequentially installed based on the flow direction of water.

In addition, the controller 180 may be connected to the flow rate sensor 620 to receive flow rate information detected by the flow rate sensor 620 . And by utilizing the received flow rate information, it is possible to control the output of the hot water module 170.

<Jungon Water>

7 to 8 are control flowcharts illustrating a process in which purified water is discharged from the water purifier according to an embodiment of the present invention.

The water purifier according to an embodiment of the present invention provides cold water, purified water, and hot water outlet functions, and in the case of hot water and cold water, the purified water that has passed through the filter is heated in the hot water module or cooled in the cold water module and discharged.

On the other hand, when purified water is dispensed, the raw water passes through the filter 120 and then directly flows out through the hot water module 170 and the hot water flow path 740 .

At this time, since the purified water is not separately cooled or heated, the temperature of the water outlet of the purified water is affected by the ambient temperature.

In detail, as the temperature of the purified water outlet decreases in winter and the temperature of the outlet water of purified water rises in summer, the temperature of the purified water changes.

In particular, in winter, the temperature of the purified water is inevitably lowered due to the influence of the ambient temperature, and the cold purified water is discharged through the water outlet nozzle 430 .

The present invention solves the problem that the temperature of purified water varies due to the influence of ambient temperature as described above, so that the user can always receive purified water within a desired range.

As described above, in the case of the present invention, hot water and purified water are discharged along the same flow path.

In detail, when hot water is dispensed, purified water that has passed through the filter 120 is heated to hot water in the hot water module 170 , and then is supplied to the water outlet nozzle 430 through the hot water flow path 740 and the water outlet flow path 760 .

In addition, when purified water is dispensed, purified water passing through the filter 120 is heated to hot water in the hot water module 170 , and then supplied to the water outlet nozzle 430 through the hot water flow path 740 and the water outlet flow path 760 .

In this embodiment, when purified water is dispensed, the controller 180 may selectively operate the hot water module 170 to adjust the temperature of the purified water.

In detail, the controller 180 may turn on or off the hot water module 170 when purified water is dispensed.

In order to determine whether the hot water module 170 operates, a temperature sensor 680 for measuring the temperature of water flowing into the hot water module 170 or discharged from the hot water module 1700 may be included.

The temperature sensor 680 may be provided in plurality.

For example, the temperature sensor 680 may include a first temperature sensor that measures the temperature of the water flowing to the hot water module 170 .

At this time, the first temperature sensor is installed in at least one of the water supply passage 710, the water supply valve 630, the intermediate passage 720, the cold and hot water valve 660, and the hot water module 170, the hot water module ( 170), or the temperature of the water flowing into the hot water module 170 may be measured.

As another example, the temperature sensor 680 may include a second temperature sensor for measuring the temperature of the water inside the hot water module 170 or the water passing through the hot water module 170 .

At this time, the second temperature sensor is installed in at least one of the hot water module 170 , the hot water flow path 740 , the water outlet flow path 760 , and the water outlet valve 670 , and is installed inside the hot water module 170 or hot water. The temperature of the water passing through the module 170 may be measured.

The second temperature sensor may measure the temperature of hot water when hot water is dispensed, measure the temperature of purified water when purified water is dispensed, and provide temperature information of the measured water to the controller 180 .

On the other hand, the controller 180 receives the temperature information of the water measured by the first temperature sensor, and when the purified water is dispensed, if the temperature of the water input from the first temperature sensor is lower than a preset first reference temperature, the hot water The module 170 is controlled to be turned on.

On the other hand, when the purified water is dispensed, if the temperature of the water input from the first temperature sensor is equal to or higher than a preset first reference temperature, the hot water module 170 is controlled to be turned off.

That is, when the purified water is dispensed, if the temperature of the water input from the first temperature sensor is equal to or higher than the first preset reference temperature, the hot water module 170 maintains an off state.

For example, the first reference temperature may be set to 20°C. However, the scope of the present invention is not limited thereto, and the first reference temperature may be variously set according to a user's preference.

Hereinafter, a purified water dispensing process according to the first embodiment will be described with reference to FIG. 7 .

First, a request for purified water is inputted from the user through the operation unit. (S110)

Then, the first temperature sensor checks the temperature of the raw water or purified water flowing into the hot water module 170 (S120).

At this time, the hot and cold water valve 660 has an outlet on the hot water module 170 open, the hot water module 170 is in an off state, and the water outlet valve 670 is in an open state.

Then, the controller 180 receives the temperature information measured by the first temperature sensor, and compares it with a first reference temperature (eg, 20° C.) (S130).

In step S130 , when the temperature measured by the first temperature sensor is greater than the first reference temperature, the controller 180 maintains the hot water module 170 in an off state and flows into the hot water module 170 . The purified water is not heated.

Then, the unheated purified water discharged from the hot water module 170 is discharged to the water outlet nozzle 430 through the hot water passage 740 and the water outlet passage 760 (S150).

On the other hand, in step S130, when the temperature measured by the first temperature sensor is smaller than the first reference temperature, the controller 180 switches the hot water module 170 to an on state, and the hot water module 170 The purified water flowing into the furnace is heated. (S140)

Then, the heated purified water discharged from the hot water module 170 is discharged to the water outlet nozzle 430 through the hot water passage 740 and the water outlet passage 760. (S150)

On the other hand, as described above, when the purified water is heated when purified water is discharged, there is a risk that the temperature of the purified water becomes excessively high.

Therefore, it is necessary to limit the heating temperature of the purified water.

As described above, the temperature sensor 680 of the present invention further includes a second temperature sensor for detecting the temperature of the water discharged from the hot water module 170 and flowing toward the water outlet nozzle.

Then, the controller 180 receives the temperature information of the water measured by the second temperature sensor, and when the purified water is dispensed, if the temperature of the water input from the second temperature sensor is lower than the first preset reference temperature, the hot water The output of the module 170 is controlled to be increased.

On the other hand, the controller 180 receives the temperature information of the water measured by the second temperature sensor, and when the purified water is dispensed, if the temperature of the water input from the second temperature sensor is equal to or higher than a preset first reference temperature, the hot water module The output of 170 is controlled to be maintained or decreased.

For example, if the temperature of the water input from the second temperature sensor is greater than or equal to a preset first reference temperature and less than a preset second reference temperature, the controller 180 determines that the temperature of the purified water is within an appropriate range, It is possible to control the output of the hot water module 170 to be maintained.

As another example, if the temperature of the water input from the second temperature sensor is equal to or greater than the second preset reference temperature, the controller 180 determines that the temperature of the purified water is high, and controls the output of the hot water module 170 to decrease. Alternatively, the hot water module 170 may be controlled to be off.

For example, the second reference temperature may be set to 25°C. However, the scope of the present invention is not limited thereto, and the second reference temperature may be variously set according to a user's preference. However, the second reference temperature should be set higher than the first reference temperature.

Hereinafter, a purified water dispensing process according to the second embodiment will be described with reference to FIG. 8 .

First, a request for purified water is inputted from the user through the operation unit. (S110)

Then, the first temperature sensor checks the temperature of the raw water or purified water flowing into the hot water module 170 (S120).

At this time, the hot and cold water valve 660 has an outlet on the hot water module 170 open, the hot water module 170 is in an off state, and the water outlet valve 670 is in an open state.

Then, the controller 180 receives the temperature information measured by the first temperature sensor, and compares it with a first reference temperature (eg, 20° C.) (S130).

In step S130 , when the temperature measured by the first temperature sensor is greater than the first reference temperature, the controller 180 maintains the hot water module 170 in an off state and flows into the hot water module 170 . The purified water is not heated.

Then, the unheated purified water discharged from the hot water module 170 is discharged to the water outlet nozzle 430 through the hot water passage 740 and the water outlet passage 760 (S150).

On the other hand, in step S130, when the temperature measured by the first temperature sensor is smaller than the first reference temperature, the controller 180 switches the hot water module 170 to an on state, and the hot water module 170 The purified water flowing into the furnace is heated. (S140)

Then, the heated purified water discharged from the hot water module 170 is discharged to the water outlet nozzle 430 through the hot water passage 740 and the water outlet passage 760. (S150)

And, in the step S150, that is, in the process of performing purified water extraction, feedback control of the hot water module 170 is simultaneously performed.

First, the second temperature sensor measures the temperature of the purified water. (S160)

Then, the controller 180 re-compares the temperature measured by the second temperature sensor with the first reference temperature. (S170)

As a result of the comparison in step S170 , when the temperature measured by the second temperature sensor is smaller than the first reference temperature, the controller 180 increases the output of the hot water module 170 . (S171)

For reference, after step S171, in order to check the temperature of the purified water to be dispensed, the process may return to step S160.

On the other hand, as a result of the comparison in step S170 , when the temperature measured by the second temperature sensor is greater than the first reference temperature, the controller 180 maintains or increases the output of the hot water module 170 .

And, in order to determine whether to increase or maintain the output of the hot water module 170, the control unit 180 compares the temperature measured by the second temperature sensor with a second reference temperature (eg, 25 ℃). ( S180)

Here, the second reference temperature may be adopted within a temperature greater than the first reference temperature.

As a result of the comparison in step S180, if the temperature measured by the second temperature sensor is less than the second reference temperature, the controller 180 maintains the output of the hot water module 170. (S181)

For reference, after step S181, in order to check the temperature of the purified water to be discharged, the process may return to step S160.

On the other hand, as a result of the comparison in step S180, if the temperature measured by the second temperature sensor is greater than the second reference temperature, the controller 180 determines that the purified water is overheated, and controls the output of the hot water module 170 to decrease. (S182)

In step S182, the control unit 1800 may turn off the hot water module 170.

For reference, after step S182, in order to check the temperature of the purified water to be dispensed, the process may return to step S160.

And, when the water out of purified water is finished, the control unit 180 controls the water outlet valve 670 to close, and controls the hot water module 170 to be turned off as well.

In the present invention, when purified water is dispensed, the obtained temperature is checked, and when the obtained temperature is lower than the set reference temperature, the purified water is heated, so that the purified water of the set temperature can be discharged instead of the cold purified water.

On the other hand, in summer, the temperature of purified water rises due to the influence of the ambient temperature, and lukewarm purified water is discharged through the water outlet nozzle.

The present invention compares the temperature of water detected by the first temperature sensor with a second reference temperature, and when the temperature of water detected by the first temperature sensor compared to the second reference temperature is high, it is determined that the purified water is lukewarm, and Cold water may be mixed and supplied to the water outlet nozzle 430 side.

First, when purified water is dispensed, the controller 180 receives information about the temperature of water measured by the first temperature sensor or the second temperature sensor.

Then, the temperature sensed by the first temperature sensor or the second temperature sensor is compared with a second reference temperature (eg, 25° C.).

When the temperature sensed by the first temperature sensor or the second temperature sensor is lower than the second reference temperature, purified water is dispensed without mixing cold water. At this time, only the hot water module 170 side outlet of the cold and hot water valve 660 is opened, and the cold water module 150 side outlet is blocked.

On the other hand, when the temperature sensed by the first temperature sensor or the second temperature sensor is higher than the second reference temperature, the controller 180 mixes the purified water with cold water and lowers the temperature of the purified water to proceed with the extraction. At this time, the cold and hot water valve 660 has both the hot water module 170 side outlet and the cold water module 150 side outlet open.

At this time, the control unit 180 opens both outlets of the cold and hot water valve 660 at the same time, the outlet of the cold water flow path 750 is opened for a first time, then is controlled to be blocked, and the hot water module 170 The outlet on the side of the intermediate flow path 720 connected to the can also be controlled to be opened for the first time.

In the case of the present invention, the temperature of the water is checked when the purified water is dispensed, and if the temperature of the water is greater than the second reference temperature, a part of the cold water is added to the purified water to keep the temperature of the purified water supplied to the user lower than the second reference temperature. have.

In addition, in the process of mixing purified water and cold water and discharging water, the temperature of the water is sensed in real time, and when the temperature of the water discharged is lower than the first reference temperature, the cold water valve 660 is controlled to control the cold water mixed into the purified water. It is also possible to reduce the amount of water or to dispense only purified water without mixing cold water with purified water.

Accordingly, when purified water is dispensed, warm water is not discharged due to the surrounding environment, and purified water having a temperature desired by the user may be dispensed.

For example, the user may be provided with an integer in the range of 20°C-25°C at all times.

Claims (16)

In the water purifier that dispenses hot water and purified water,
a housing forming a storage space;
a filter provided inside the housing to purify water supplied from an external water supply source;
a water supply passage for guiding the water supplied from the water supply source toward the filter;
a water inlet valve installed in the water supply passage to control the flow of water flowing toward the filter;
a water outlet nozzle provided on the outside of the housing, the water passing through the filter is taken out;
a hot water module that forms a heating flow path through which the purified water passing through the filter passes, and heats the purified water passing through the heating flow path into hot water when hot water is discharged;
a hot water flow path for guiding the hot water passing through the hot water module toward the water outlet nozzle;
A control unit for controlling the operation of the water inlet valve and the hot water module,
When purified water is dispensed, purified water passing through the filter flows toward the water outlet nozzle through the hot water module and the hot water flow path, and the controller selectively operates the hot water module.
The method of claim 1,
The control unit is
When purified water is dispensed, the hot water module is turned on or off,
A water purifier that turns on the hot water module when hot water is dispensed.
3. The method of claim 2,
The water purifier further comprising a first temperature sensor for measuring the temperature of the water flowing to the hot water module.
4. The method of claim 3,
The control unit receives the temperature information of the water measured by the first temperature sensor,
A water purifier that turns on the hot water module when the temperature of the water input from the first temperature sensor is lower than a preset first reference temperature when purified water is dispensed.
5. The method of claim 4,
The water purifier further comprising a second temperature sensor for sensing a temperature of water discharged from the hot water module and flowing toward the water outlet nozzle.
6. The method of claim 5,
The control unit receives the temperature information of the water measured by the second temperature sensor,
A water purifier that controls the output of the hot water module to increase when the temperature of the water input from the second temperature sensor is lower than a preset first reference temperature when purified water is dispensed.
6. The method of claim 5,
The control unit receives the temperature information of the water measured by the second temperature sensor,
A water purifier that controls the output of the hot water module to be maintained or decreased when the temperature of the water input from the second temperature sensor is equal to or higher than a preset first reference temperature when purified water is dispensed.
8. The method of claim 7,
The control unit, when the temperature of the water input from the second temperature sensor is greater than or equal to a preset first reference temperature and less than a preset second reference temperature, the water purifier to control the output of the hot water module to be maintained.
8. The method of claim 7,
The control unit, when the temperature of the water input from the second temperature sensor is equal to or greater than a preset second reference temperature, the water purifier to control the output of the hot water module to decrease.
4. The method of claim 3,
The control unit receives the temperature information of the water measured by the temperature sensor,
A water purifier that turns off the hot water module when the temperature of the input water is greater than or equal to a preset first reference temperature when purified water is dispensed.
The method of claim 1,
It further comprises a water outlet flow path having one side connected to the hot water flow path and the other side connected to the water outlet nozzle,
The water purifier is provided with a water outlet valve controlling the flow of water flowing toward the water outlet nozzle in the water outlet passage.
12. The method of claim 11,
The water outlet valve is provided as a three-way valve, and a drain flow path is connected to the water outlet valve,
The water outlet valve is a water purifier for flowing the introduced water toward the water outlet nozzle or to the drain passage;
13. The method of claim 12,
When hot water is dispensed, the water outlet valve is opened toward the water outlet nozzle,
When the hot water is discharged, the water outlet valve is opened toward the drain flow path to drain the remaining water.
The method of claim 1,
an intermediate flow path having one end connected to the outlet side of the filter and the other end connected to the inlet side of the hot water module, guiding the water passing through the filter toward the hot water module;
a cold water passage having one side branched from the intermediate flow passage and the other side joining the water outlet passage connected to the water outlet nozzle;
The water purifier further comprising a cold water module installed in the cold water flow path to cool the purified water passing through the cold water flow path with cold water.
15. The method of claim 14,
A cold and hot water valve is installed in the intermediate flow path at a branch point of the cold water flow path,
When hot water is released or purified water is dispensed, the cold and hot water valve is opened toward the hot water module,
When cold water is exported, the cold and hot water valve is opened toward the cold water flow path.
15. The method of claim 14,
After hot water is dispensed, if purified water is dispensed within the first set time,
The cold and hot water valve is a water purifier that is opened toward the hot water module and the cold water flow path.

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