KR20190058910A - Water purifier having ice manufacturing function and operation method thereof - Google Patents

Abstract

Disclosed are a water purifier having an ice-making function and an operation method thereof. According to the present invention, the water purifier having an ice-making function can comprise: an auger module which generates cold water and ice by an auger-type ice-making method; a cooler which provides a refrigerant to the auger module; a cold water storage unit which stores the cold water generated by the auger module, and discharges the stored cold water; an ice storage unit which stores the ice generated by the auger module, and discharges the stored ice; a temperature sensor which detects the temperature of the cold water stored in the cold water storage unit; a full ice level sensor which detects whether the ice storage unit is full of ice or not; an input unit which receives a user input for selecting an operation mode; and a control unit which, in accordance with the operation mode selected through the input unit, controls the operation of the auger module and the cooler based on a signal transmitted from the temperature sensor or the full ice level sensor. The present invention aims to provide a water purifier which is able to prevent an auger module from freezing and to properly generate cold water and ice in accordance with a user′s request.

Description

TECHNICAL FIELD [0001] The present invention relates to a water purifier having an ice making function and a method of operating the water purifier.

The present invention relates to a water purifier having an ice making function and an operation method thereof.

A water purifier is a device for purifying raw water supplied from the outside and providing purified water. Recently, in addition to providing purified water, a water purifier for generating and providing ice using a purified water is widely used.

There are various methods of generating ice such as an immersion ice-making method, a spray-type ice-making method, a water-based ice-making method, and an auger-type ice-making method.

Here, in the auger type ice making system, the refrigerant flows around the flow space in which the water flows, so that ice is generated on the inner circumferential surface of the flow space, and the screw is rotated in the flow space to separate ice from the inner circumferential surface of the flow space And then discharged to the outside.

Such auger type ice-making method is mainly used in an ice-maker used for business. Commercial ice makers use a high-performance cooler, so ice can be used regardless of the water temperature. However, when performance of a cooler such as a domestic water purifier is deteriorated, it is difficult to make normal ice making using normal temperature water.

Therefore, in the case of a domestic water purifier employing an auger type ice-making system, in order to perform the ice-making function, a cooling function for lowering the water temperature must be preceded. However, in this process, the auger module is frozen, which may make it difficult to circulate the water smoothly. In addition, when the cooling function is given priority in this way, the ice-making operation can not be sufficiently performed and ice may become insufficient.

Therefore, in the related art, there is a demand for a method for appropriately generating cold water and ice according to a user's demand while preventing freezing of the auger module in a domestic water purifier employing the auger type ice-making system.

In order to solve the above problems, an embodiment of the present invention provides a water purifier provided with an icemaker.

Wherein the water purifier having the ice making function includes an auger module for generating cold water and ice by an auger type ice making system; A cooler for providing refrigerant to the auger module; A cold water storage unit for storing the cold water generated by the auger module and discharging the stored cold water; An ice storage part for storing the ice produced by the auger module and discharging the stored ice; A temperature sensor for sensing the temperature of the cold water stored in the cold water storage unit; A full ice level sensor for detecting whether or not the ice stored in the ice storage unit is full; An input unit receiving a user input for selecting an operation mode; And a controller for controlling the operation of the auger module and the cooler based on a signal received from the temperature sensor or the full ice level sensor according to an operation mode selected through the input unit.

Meanwhile, another embodiment of the present invention provides a method of operating a water purifier having an ice making function.

The operation method of the water purifier provided with the ice making function is characterized in that the operation method of the water purifier includes an auger module for generating cold water and ice by an auger type ice making system, Setting an operation mode; And controlling the operation of the auger module based on the temperature of the stored cold water or whether the stored ice is full, depending on the set operation mode.

In addition, the means for solving the above-mentioned problems are not all enumerating the features of the present invention. The various features of the present invention and the advantages and effects thereof will be more fully understood by reference to the following specific embodiments.

According to an embodiment of the present invention, it is possible to appropriately generate cold water and ice according to a user's demand, while preventing the auger module from freezing in a water purifier employing the auger type ice-making system.

1 is a configuration diagram of a water purifier having an ice making function according to an embodiment of the present invention.
2 is a detailed configuration diagram of the auger module shown in FIG.
Fig. 3 is a diagram showing an embodiment of the auger module shown in Fig. 1. Fig.
4 is a flowchart illustrating a method of operating a water purifier having an ice making function according to another embodiment of the present invention.
FIG. 5 is a flowchart of an operation method of a water purifier provided with an ice-making function in the cooling priority mode shown in FIG.
FIG. 6 is a flowchart of an operation method of a water purifier provided with an ice-making function in the case of the ice-making priority mode shown in FIG.
FIG. 7 is a flowchart of an operation method of a water purifier provided with an ice making function in the case of the optimization mode shown in FIG.
FIG. 8 is a flowchart of an operation method of a water purifier provided with an ice-making function in a case where the cooling priority mode, the ice-making priority mode and the optimization mode are not all included in FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

1 is a configuration diagram of a water purifier having an ice making function according to an embodiment of the present invention.

1, the water purifier 100 includes a filter unit 110, a purified water storage unit 120, a cold water and ice storage unit 130, an auger module 140, a cooler 145, an extraction unit 150, A control unit 160, a sensor unit 170, and an input unit 180.

The filter unit 110 may include a sediment filter, a pre-carbon filter, a reverse osmosis membrane filter, and a post-carbon filter. The filter unit 110 includes at least one filter, The number and the order of the filters may be changed according to the filtering method of the water purifier 100 or the filtering performance required of the water purifier 100. For example, a hollow fiber membrane filter may be provided instead of the reverse osmosis membrane filter. In addition, a post-carbon filter may not be provided, or a micro filter MF or another functional filter may be provided in place of or in addition to the above-described filter.

The constant storage unit 120 passes through the filter unit 110, stores the purified integer, and can selectively discharge the stored constant.

For example, the constant stored in the constant storage unit 120 may be extracted to the extraction unit 150 such as a powder set or the cold water and ice storage unit 130 through the first flow path switching valve SV1.

The first flow path switching valve SV1 is provided in a flow path connecting the purified water storage unit 120 and the cold water and ice storage unit 130 and the extraction unit 150, You can switch.

For example, the first flow-path switching valve SV1 may be implemented as a two-way valve so that a constant stored in the constant storage 120 may be provided to the extractor 150, The flow path can be switched to be provided to the cold water and ice storage unit 130. [

In this case, the purified water passing through the filter unit 110 may be directly extracted into the extracting unit 150 or the cold water and ice storage unit 130 ). ≪ / RTI >

The cold water and ice storage unit 130 may store cold water or ice that is provided from the purified water storage unit 120 and cooled by the auger module 140 to be described later, and may selectively discharge the stored cold water or ice.

The cold water and ice storage unit 130 may be divided into a first storage space for storing cold water by a partition (not shown) provided therein and a second storage space for storing ice, have.

In this case, the integer provided from the constant storage unit 120 may be introduced into the first storage space and then supplied to the auger module 140, which will be described later, to be cooled. In addition, the cold water generated by the auger module 140 may be supplied to the cold water and ice storage unit 130 and stored in the first storage space. Meanwhile, the ice generated by the auger module 140 may be supplied to the cold water and ice storage 130 and stored in the second storage space.

However, as shown in FIG. 1, the storage unit for storing the cold water and the ice is not necessarily formed as one unit, but the cold water storage unit and the ice storage unit may be located adjacent to each other.

The pump P1 and the second flow path switching valve SV2 may be provided in the flow path connecting the first storage space of the cold water and ice storage unit 130 and the auger module 140. [

Here, the pump P1 may be implemented, for example, as a motor so that cold water stored in the first storage space may be provided to the auger module 140. [

The second flow path switching valve SV2 may be implemented, for example, as a two-way valve so that the cold water stored in the first storage space of the cold water and ice storage unit 130 is supplied to the extraction unit 150, 140). ≪ / RTI >

On the other hand, the second storage space of the cold water and ice storage unit 130 is provided with a transfer means (not shown) for transferring ice, and the ice transferred by the transfer means is extracted through the extraction unit 150 .

The auger module 140 is for generating cold water and ice by cooling the cold water (or purified water) provided from the cold water and ice storage part 130 by the auger type ice-making method.

FIG. 2 is a detailed configuration diagram of the auger module shown in FIG. 1, and FIG. 3 is a diagram illustrating an example of the auger module shown in FIG. 1. The auger module 140 includes a cooling unit 142, A transfer unit 144, a separation transfer unit 146, and a motor 148. [

The cooling unit 142 constitutes the outer periphery of the auger module 140 and the cooling unit 142 is formed with a space through which the refrigerant can flow so that the coolant supplied from the cooler 145, .

In addition, the fluid portion 144 formed in the inner space surrounded by the cooling portion 142 receives and flows the cold water provided from the cold water and ice storage portion 130. The cold water flowing in the flow portion 144 is further cooled by the refrigerant flowing in the cooling portion 142 and ice can be generated on the surface in contact with the cooling portion 142. [

Here, the flow rate of the cold water flowing through the flow portion 144 may vary depending on whether the pump P1 is driven. For example, when the pump P1 is driven, the flow velocity is increased, so that no ice is generated in the flow portion 144 or only a relatively small amount of ice can be generated. On the other hand, if the pump P1 is not driven, the flow velocity is slowed and ice can be sufficiently generated.

The separating transfer part 146 is implemented, for example, as a screw rotating in the floating part 144 to separate and transfer the generated ice to the surface in contact with the cooling part 142 and discharge it to the cold water and ice storage part 130 have.

The motor 148 is driven to rotate the separation transfer unit 146.

The cold water generated by the auger module 140 is supplied to the first storage space of the cold water and ice storage unit 130 and the ice generated by the auger module 140 is supplied to the ice storage unit 130 And may be provided as a second storage space.

The cooler 145 is for providing the coolant to the cooling unit 142 of the auger module 140 and includes a compressor for compressing the coolant and a cooler for cooling the coolant by discharging heat from the coolant of high temperature and pressure, And a cooling fan which is selectively driven at the time of driving the compressor to radiate heat.

The extraction unit 150 is for selectively extracting the cold water stored in the first storage space and the ice stored in the second storage space of the purified water, cold water, and ice storage unit 130 stored in the purified water storage unit 120, And can be implemented as a powder set for extracting purified water and cold water and as an extracting bowl for extracting ice.

The control unit 160 controls the overall operation of the water purifier 100 and includes a central processing unit (CPU), a graphics processing unit (GPU), a microprocessor, an application specific integrated circuit (ASIC) Programmable gate arrays (FPGAs), and the like.

For example, when the operation mode is selected by the user through the input unit 180 and the water purifier 100 is operated, the controller 160 controls the operation of the water purifier 100 according to the selected operation mode, The cooler 145 and the motor 148 included in the auger module 140 may be controlled according to a signal or a predetermined operation time condition to perform a cooling function and an icing function.

A specific method of controlling the operation of the water purifier 100 according to the operation mode selected by the user by the controller 160 will be described later with reference to FIG. 4 to FIG.

The sensor unit 170 is for sensing information necessary for controlling the operation of the water purifier 100.

For example, the sensor unit 170 includes a first temperature sensor for sensing the temperature of the cold water stored in the first storage space of the cold water and ice storage unit 130, a second temperature sensor for sensing the ambient temperature, And a fullness sensor for detecting whether the ice stored in the second storage space of the ice storage unit 130 is full.

The input unit 180 receives a user's input for controlling the operation of the water purifier 100, and may be implemented by, for example, a mechanical button or a touch button.

For example, an input for selecting an operation mode of the water purifier 100 may be received through the input unit 180 and transmitted to the controller 160. Here, the operation mode of the water purifier 100 may include a cooling priority mode, an ice-making priority mode, and an optimization mode. The cooling priority mode is an operation mode that prioritizes keeping the temperature of the cold water below a predetermined temperature. The ice-making priority mode is an operation mode that prioritizes keeping the ice amount at maximum, that is, close to full ice or full ice. Mode is an intermediate mode between the cooling priority mode and the ice making priority mode and is an operation mode in which the temperature of the cold water can be maintained at an appropriate level or lower while increasing the amount of ice as much as possible.

4 is a flowchart illustrating a method of operating a water purifier having an ice making function according to another embodiment of the present invention.

Referring to FIG. 4, when power is supplied to the water purifier for the first time (S41), the user can receive an input for selecting the operation mode of the water purifier (S42).

It is determined whether the operation mode of the water purifier selected by the user is the cooling priority mode (S43), the ice-making priority mode (S44), the optimization mode (S45) ), And the operation of the auger module can be controlled based on the temperature of the cold water or whether or not the ice is full by proceeding to A, B, C or D, respectively.

On the other hand, if the operation mode of the water purifier is not selected after the initial operation of the water purifier, the water purifier can operate in a predetermined default mode (for example, a cooling priority mode).

FIG. 5 is a flowchart of an operation method of a water purifier provided with an ice making function in the case of the cooling priority mode shown in FIG. 4, wherein the cooling priority mode is an operation mode in which priority is given to keeping the temperature of the cold water below a predetermined temperature .

5, when the cooling condition is satisfied (S50), the cooling operation and the additional cooling operation are performed to lower the temperature of the cold water used for the ice making (S51, S52), and when the icing condition is satisfied (S53) The ice making operation is performed to generate ice (S54), and then the ice making operation is performed to prevent the auger module from freezing (S55).

More specifically, if the predetermined cooling condition (for example, when the cold water temperature is equal to or higher than the preset temperature) is satisfied (S50), the cooling operation can be performed (S51).

In the cooling operation step S51, the water is circulated in the auger module to lower the temperature of the cold water. The pump for supplying cold water stored in the first storage space of the cold water and ice storage unit to the auger module is ON, The compressor of the cooler for providing the coolant to the cooling part of the module can be controlled to be ON and the motor of the auger module can be controlled to be OFF and the cooling fan of the cooler can be controlled when the outside air temperature is higher than a predetermined temperature (for example, ON can be controlled.

The cooling operation step S51 may be performed until the cold water stored in the first storage space of the cold water and ice storage unit reaches a predetermined temperature (for example, 4 DEG C) and then proceed to the next step.

Then, the additional cooling operation step S52 is performed to lower the temperature of the cold water by allowing the water to circulate in the auger module. The pump can be controlled to ON, the compressor of the cooler to ON, and the motor to be ON, The cooling fan of the cooler can be controlled to be ON when the outside air temperature is equal to or higher than a predetermined temperature (for example, 10 DEG C).

In the additional cooling operation step S52, the motor may be controlled to be turned on differently from the cooling operation step S51 in order to prevent the cold water from being overcooled while the temperature of the cold water is further lowered.

The above-described additional cooling operation step S52 may be performed for a predetermined time (for example, 5 minutes), or when the cold water stored in the first storage space of the cold water and ice storage is cooled to a predetermined temperature (for example, And then proceed to the next step.

Thereafter, if a predetermined ice-making condition (for example, when no ice-full is detected) is satisfied (S53), the ice-making operation can be performed (S54).

The ice making operation step S54 is for generating ice by the auger module. The ice making operation may be performed by turning off the pump, turning on the compressor of the cooler, and turning on the motor. If the outside air temperature is lower than a predetermined temperature 10 ° C) or more, the cooling fan of the cooler can be controlled to be turned ON.

The ice-making operation performing step S54 may be performed until the cold water stored in the first storage space of the cold water and ice storage reaches a predetermined temperature (for example, 6.8 DEG C) and then proceed to the next step. Also, even if the cold water stored in the first storage space of the cold water and ice storage unit does not reach a predetermined temperature (for example, 6.8 ° C), the second storage space of the cold water and ice storage unit is filled with ice, The ice-making operation performing step S54 may be terminated and the process may proceed to the next step.

Hereinafter, the thaw operation operation step S55 is for thawing the auger module, and the pump can be controlled to be OFF, the compressor of the cooler and the cooling fan to be OFF, and the motor to be ON.

The above-described sea ice operation operation step S55 may be performed for a predetermined time, and in this case, the sea ice operation execution time may be set differently considering the ambient temperature. For example, when the outside air temperature is 25 ° C or higher, the sea ice operation is performed for 15 minutes, and when the outdoor air temperature is lower than 25 ° C, the sea ice operation is performed for 25 minutes.

Thereafter, the ice making operation by the auger module is completed, and both the pump, the cooler, and the motor can be controlled to be OFF (S56).

Thereafter, if the predetermined cooling condition (for example, the cold water temperature is equal to or higher than the preset temperature) or the icing condition (for example, when no ice cubes are detected) is satisfied (S57), the initial cooling operation can be performed S59).

The initial cooling operation execution step (S59) is for the thawing of the auger module. The pump is ON, the compressor of the cooler and the cooling fan are OFF, and the motor is OFF. Here, unlike the sea ice operation step S55, the noise of the motor operation can be improved by controlling the motor to be OFF.

The initial cooling operation step S59 may be performed for a predetermined time (for example, three minutes), and then the cooling operation may be performed in step S51.

If the temperature of the cold water stored in the first storage space rises or the cooling operation is switched to the cooling operation during the cooling operation, the possibility of freezing the auger module is low. Therefore, (S59) can be omitted.

On the other hand, if the cooling condition and the deicing condition are not satisfied (S57), the apparatus can enter the standby mode (S58).

FIG. 6 is a flowchart of an operation method of a water purifier provided with an ice making function in the case of the ice making priority mode shown in FIG. 4, wherein the ice making priority mode is to keep the ice amount at the maximum, that is, It is a priority operation mode.

6, unlike the cooling priority mode shown in FIG. 5, the ice-making operation mode S64 is performed in a state where ice is filled in the second storage space of the cold water and ice storage unit, that is, (S65) until a predetermined time (for example, one hour) elapses before proceeding to the next step.

As described above, once the ice making operation is started in the ice-making priority mode, the ice is sufficiently generated without considering the cold water temperature, so that the ice can meet the demand of the desired user.

Except for this, the remaining operations are the same as those in the cooling priority mode shown in FIG. 5, and a duplicate description thereof will be omitted.

FIG. 7 is a flowchart of an operation method of a water purifier having an ice making function in the case of the optimization mode shown in FIG. 4, wherein the optimization mode is an intermediate step between the cooling priority mode and the ice making priority mode, This is an operation mode in which the temperature can be maintained at an appropriate level or lower.

7, the optimization mode is different from the ice making priority mode shown in FIG. 6 in that the ice making operation step S74 is performed until a predetermined time (for example, 30 minutes) elapses (S75) And then proceed to the next step.

As described above, in the optimization mode, once the ice making operation is started, ice is generated without considering the cold water temperature, and ice is generated for a minimum of time. As a result, the cold water temperature can be maintained at a certain level or lower while the ice shortage phenomenon is improved.

Except for this, the remaining operations are the same as those in the cooling priority mode shown in FIG. 5, and a duplicate description thereof will be omitted.

FIG. 8 is a flowchart of an operation method of a water purifier provided with an ice-making function in a case where the cooling priority mode, the ice-making priority mode and the optimization mode are not all included in FIG.

Referring to FIG. 8, if the cooling condition is satisfied (S80), the cooling operation and the additional cooling operation are performed (S81, S82), and then the apparatus can enter the standby mode (S83). Here, the cooling operation and the additional cooling operation are the same as those described in the above-described steps S51 and S52, and a duplicate description thereof will be omitted.

Thereafter, if the predetermined cooling condition (for example, the cold water temperature is equal to or higher than the predetermined temperature) is satisfied (S80), the process may proceed to the cooling operation performing step S81 described above.

According to an embodiment of the present invention, the operation can be performed according to the operation mode selected by the consumer as described above with reference to FIGS.

Further, the selection of the operation mode can be made at any time during the operation of the water purifier as well as during the initial operation of the water purifier.

For example, when there is a change from the ice-making priority mode or the optimization mode to the cooling priority mode, if the operation mode is changed during the ice making operation, the temperature of the cold water reaches a predetermined temperature (for example, 6.8 DEG C) And then proceed to the thawing operation performing step. If the temperature of the cold water has reached the predetermined temperature at the time when the operation mode is changed, the operation can be immediately proceeded to the sea ice operation performing step.

However, when there is a change in the operation mode between the optimization mode and the ice-making priority mode, particularly when the operation mode is changed during the ice-making operation, the difference in the predetermined time for performing the ice- Can be processed. Here, the time for maintaining the ice-making operation in the ice-making priority mode is set to a first time (for example, one hour), the time for maintaining the ice-making operation in the optimization mode is set to a second time (for example, The first time may be longer than the second time.

1) When changing from the optimization mode to the ice-making priority mode (mode change at a time when the ice-making operation is performed for a third time (for example, 20 minutes) shorter than the second time) (E.g., (second time - third time) + (first time - second time)) (for example, 40 minutes)

2) When changing from the ice-making priority mode to the optimization mode (when the ice-making operation is performed for a third time (for example, 20 minutes) shorter than the second time mode change): switch to the optimization mode, Second time-third time) (for example, 10 minutes), and then proceeds to the thawing operation performing step

3) When the mode is changed from the ice-making priority mode to the optimization mode (when the ice-making operation is performed for the fourth time (for example, 40 minutes) longer than the second time mode change): switch to the optimization mode, Proceed to step

The present invention is not limited to the above-described embodiments and the accompanying drawings. It will be apparent to those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: water purifier
110:
120:
130: cold water and ice storage
140: auger module
145: Cooler
150:
160:
170:
180: input

Claims (18)

An auger module for generating cold water and ice by an auger type ice-making method;
A cooler for providing refrigerant to the auger module;
A cold water storage unit for storing the cold water generated by the auger module and discharging the stored cold water;
An ice storage part for storing the ice produced by the auger module and discharging the stored ice;
A temperature sensor for sensing the temperature of the cold water stored in the cold water storage unit;
A full ice level sensor for detecting whether or not the ice stored in the ice storage unit is full;
An input unit receiving a user input for selecting an operation mode; And
And a controller for controlling operations of the auger module and the cooler based on a signal received from the temperature sensor or the full ice level sensor according to an operation mode selected through the input unit.
The method according to claim 1,
The operation mode includes:
A cooling priority mode for preferentially keeping the temperature of the cold water stored in the cold water storage unit below a predetermined temperature;
An ice-making priority mode in which priority is given to keeping the amount of ice stored in the ice storage unit at a maximum; And
And an ice-making function including an optimization mode which is an intermediate step between the cooling-priority mode and the ice-making priority mode.
3. The method of claim 2,
Wherein the control unit sequentially performs a cooling operation and an additional cooling operation when the cooling priority mode is selected and satisfies a predetermined cooling condition, and if the predetermined operation condition is satisfied, A module and an operation of the cooler,
And an ice-making function for controlling the ice-making operation to be performed until the temperature of the cold water sensed by the temperature sensor reaches a predetermined temperature.
3. The method of claim 2,
Wherein the control unit sequentially performs a cooling operation and an additional cooling operation when the predetermined cooling condition is satisfied when the ice-making priority mode is selected, and sequentially performs the ice-making operation and the thawing operation when the predetermined ice- A module and an operation of the cooler,
And an ice making function for controlling the ice making operation to be performed by the full ice level sensor until the full ice level is sensed or for a predetermined first time.
3. The method of claim 2,
Wherein the control unit sequentially performs a cooling operation and an additional cooling operation when the predetermined cooling condition is satisfied, and sequentially performs the ice-making operation and the thawing operation when the predetermined ice-making condition is satisfied, And controlling the operation of the cooler,
And an ice-making function for controlling the ice-making operation to be performed for a second predetermined time.
3. The method of claim 2,
Wherein the time for maintaining the ice-making operation in the ice-making priority mode is set to a first time, the time for maintaining the ice-making operation in the optimization mode is set to a second time, and if the first time is longer than the second time,
When the operation mode is changed from the optimization mode to the ice-making priority mode at the time of performing the ice-making operation for a third time shorter than the second time,
Wherein the controller further has an ice making function for controlling the ice making operation to be performed after the ice making operation is further performed during ((second time - third time) + (first time - second time)).
The method according to claim 6,
When the operation mode is changed from the ice-making priority mode to the optimization mode at the time of performing the ice-making operation for the third time,
Wherein the control unit further includes an ice making function for controlling the ice making operation to be performed after the ice making operation is further performed for a second time period to a third time period.
The method according to claim 6,
When the operation mode is changed from the ice-making priority mode to the optimization mode at the time of performing the ice-making operation for the fourth time longer than the second time,
Wherein the controller controls the ice maker to perform the ice making operation immediately.
The method of claim 3,
When the operation mode is changed from the ice making priority mode or the optimization mode to the cooling priority mode while the ice making operation is being performed and the temperature of the cold water reaches the preset temperature at the time when the operation mode is changed,
Wherein the control unit immediately controls the ice making operation to be performed.
A method for operating a water purifier including an auger module for generating cold water and ice by an auger type ice-making system,
Setting an operation mode according to a user's input for selecting an operation mode of the water purifier; And
And controlling the operation of the auger module based on the stored cold water temperature or whether or not the stored ice is full according to the set operation mode.
11. The method of claim 10,
The operation mode includes:
A cooling priority mode for preferentially keeping the temperature of the cold water below a predetermined temperature;
An ice-making priority mode in which priority is given to keeping the stored amount of ice at a maximum; And
And an ice-making function including an optimization mode which is an intermediate stage between the cooling priority mode and the ice-making priority mode.
12. The method of claim 11,
Wherein controlling the operation of the auger module comprises:
When the set operation mode is the cooling priority mode,
Sequentially performing a cooling operation and an additional cooling operation when the predetermined cooling condition is satisfied; And
And performing the ice-making operation and the sea-ice operation in sequence when the predetermined ice-making condition is satisfied,
Wherein the ice making operation is performed until the temperature of the cold water reaches a predetermined temperature.
12. The method of claim 11,
Wherein controlling the operation of the auger module comprises:
When the set operation mode is the above-mentioned ice-making priority mode,
Sequentially performing a cooling operation and an additional cooling operation when the predetermined cooling condition is satisfied; And
And performing the ice-making operation and the sea-ice operation in sequence when the predetermined ice-making condition is satisfied,
Wherein the ice making operation has an ice making function performed until a full ice level is sensed or for a predetermined first time.
12. The method of claim 11,
Wherein controlling the operation of the auger module comprises:
When the set operation mode is the optimization mode,
Sequentially performing a cooling operation and an additional cooling operation when the predetermined cooling condition is satisfied; And
And performing the ice-making operation and the sea-ice operation in sequence when the predetermined ice-making condition is satisfied,
Wherein the ice making operation is performed for a second predetermined time.
12. The method of claim 11,
Wherein the time for maintaining the ice-making operation in the ice-making priority mode is set to a first time, the time for maintaining the ice-making operation in the optimization mode is set to a second time, and if the first time is longer than the second time,
When the operation mode is changed from the optimization mode to the ice-making priority mode at the time of performing the ice-making operation for a third time shorter than the second time,
And an ice-making function for performing the ice-making operation after the ice-making operation is further performed ((second time - third time) + (first time - second time)).
16. The method of claim 15,
When the operation mode is changed from the ice-making priority mode to the optimization mode at the time of performing the ice-making operation for the third time,
And an ice-making function for further performing the ice-making operation (second time-third time) before performing the ice-making operation.
16. The method of claim 15,
When the operation mode is changed from the ice-making priority mode to the optimization mode at the time of performing the ice-making operation for the fourth time longer than the second time,
And an ice-making function for performing a sea-ice operation immediately.
13. The method of claim 12,
When the operation mode is changed from the ice making priority mode or the optimization mode to the cooling priority mode while the ice making operation is being performed and the temperature of the cold water reaches the preset temperature at the time when the operation mode is changed,
And an ice-making function for immediately performing the sea-ice operation.

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