KR101478897B1 - Water purifier and method for controlling the same - Google Patents

Abstract

The present invention relates to a water purifier. A water purifier according to one aspect, comprising: a main body; A ice making part provided in the body and generating ice; An ice storage part for storing the ice produced in the ice making part; An ice discharge unit provided in the main body and through which the ice stored in the ice storage unit is taken out; And a heating unit for heating the ice storage unit.

Description

Water purifier and method of controlling same

The present invention relates to a water purifier and a control method thereof.

Generally, a water purifier is a device for purifying raw water such as tap water to be suitable for drinking. The water purifier may be divided into a water purifier that stores the purified water after storing the purified water in the water tank, and a water purifier that discharges the purified water without storing the purified water.

A conventional water purifier may include an ice reservoir in which ice is stored, as disclosed in Korean Patent Publication No. 2012-0110735. A drain hole is formed in the ice reservoir. Therefore, the water generated as the ice melts is not accumulated together with the ice, but can be discharged through the drain.

However, in the conventional water purifier, even if water can be discharged in the state where the ice making function is off, the water droplets formed on the inner surface of the ice reservoir or on the ice transfer member are not easily discharged through drainage. In this case, there is a problem that the water droplets formed on the ice-free ice transfer member or the like on the inner surface of the ice storage tank propagate bacteria or mold.

It is an object of the present invention to provide a water purifier and a control method capable of drying a space in which an ice storage unit or an ice storage unit is accommodated.

A water purifier according to one aspect, comprising: a body having a filter; A ice making unit for generating ice by receiving purified water by a filter of the main body; An ice storage part for storing the ice produced in the ice making part; An ice discharge unit provided in the main body and through which the ice stored in the ice storage unit is taken out; And a heating unit for heating the ice storage unit.

Further comprising a mode selection unit for turning on or off the ice making function, and when the ice making function is turned off by the mode selecting unit, the heating unit can be turned on.

The heating unit may be turned off when the heating unit is turned on and the reference time has elapsed.

And a shutter for selectively communicating the ice discharger and the ice reservoir, and the shutter may be opened and closed one or more times before the heating unit is turned on and the reference time elapses.

When the ice-making function is turned on by the mode selection unit before the elapse of the reference time while the heating unit is on, the heating unit can be turned off.

The apparatus may further include a temperature sensor provided in the main body, and the on reference time of the heating unit may be set differently according to the temperature sensed by the temperature sensor.

The heating unit may further include a temperature sensor provided in the main body. If the temperature detected by the temperature sensor is lower than a reference temperature, the heating unit may be turned on.

When the heating unit is turned on, the ice making in the ice making unit can be stopped.

And a shutter for selectively communicating the ice discharge unit and the ice storage unit, and the shutter may be opened and closed once after the heating unit is turned on.

When the temperature detected by the temperature sensor exceeds the reference temperature after the heating unit is turned on, the heating unit may be turned off.

When the temperature sensed by the temperature sensor does not exceed the reference temperature after the heating unit is turned on, it is determined whether the on time of the heating unit has passed the reference time. If it is determined that the on time of the heating unit has passed the reference time, The heating unit can be turned off.

The ice making operation in the ice making part can be maintained in a stopped state until the temperature sensed by the temperature sensor exceeds the reference temperature after the heating part is turned off.

The ice storage unit may further include a housing surrounding the ice storage unit, and the heating unit may be installed in the housing.

According to another aspect of the present invention, there is provided a control method for a water purifier, comprising: Wherein the operating condition of the heating unit is satisfied when the ice making function is turned on; And heating the ice storage unit storing the ice when the heating unit is satisfied with the operating condition of the heating unit.

If the operating condition of the heating unit is satisfied, the ice-making function may be turned off through the input unit, or the temperature sensed by the temperature sensor may be below the reference temperature.

The heating unit may be turned on and the heating unit may be turned off when a predetermined time has elapsed.

After the ice-making function is turned off and the heating unit is turned on, the heating unit can be turned off when the ice-making function is turned on again.

The heating unit may be turned off when the temperature detected by the temperature sensor exceeds the reference temperature and the heating unit is turned on after the temperature detected by the temperature sensor is lower than the reference temperature.
A water purifier according to another aspect includes: a body having a filter; A ice making unit for generating ice by receiving purified water by a filter of the main body; An ice storage part for storing the ice produced in the ice making part; An ice discharge unit provided in the main body and through which the ice stored in the ice storage unit is taken out; A heating unit for heating the ice storage unit; And a shutter for selectively communicating the ice discharger and the ice reservoir, wherein the shutter is opened at least once before the heating unit is turned on and off.
A water purifier according to another aspect includes: a body having a filter; A temperature sensor provided in the main body for sensing a room temperature; A ice making unit for generating ice by receiving purified water by a filter of the main body; An ice storage part for storing the ice produced in the ice making part; An ice discharge unit provided in the main body and through which the ice stored in the ice storage unit is taken out; And a heating unit for heating the ice storage unit. When the operating condition of the heating unit is satisfied, the heating unit is operated, and when the heating unit is operated, the ON reference time is set differently according to the room temperature sensed by the temperature sensor do.
A water purifier according to another aspect includes: a body having a filter; A temperature sensor provided in the main body for sensing a room temperature; A ice making unit for generating ice by receiving purified water by a filter of the main body; An ice storage part for storing the ice produced in the ice making part; An ice discharge unit provided in the main body and through which the ice stored in the ice storage unit is taken out; And a heating unit for heating the ice storage unit. When the room temperature sensed by the temperature sensor is lower than a reference temperature, the heating unit is turned on.
According to another aspect of the present invention, there is provided a control method for a water purifier, comprising: an icing function being turned on; Wherein the operating condition of the heating unit is satisfied when the ice making function is turned on; Heating the ice reservoir to store the ice when the heating unit is satisfied; And opening the shutter for selectively communicating the ice discharge part and the ice storage part to discharge the steam before the heating part is turned off.

According to the present invention, when the ice-making function is turned off, the heater is turned on to dry the ice storage unit and the housing, so that bacteria and molds can be prevented from living in the ice storage unit or the housing.

In addition, when the room temperature is lower than the reference room temperature, the ice cubes in the ice storage unit are melted and the ice making process is performed again, thereby reducing the emotional feeling of the user.

1 is a perspective view of a water purifier according to an embodiment of the present invention;
2 is an internal perspective view of a water purifier according to an embodiment of the present invention;
3 is a partial cross-sectional view of a water purifier according to one embodiment of the present invention.
4 is a perspective view showing an opening of a housing according to an embodiment of the present invention opened by an opening / closing part.
5 is a view illustrating a state in which the ice storage unit is separated from the main body according to the embodiment of the present invention.
6 is a perspective view of an ice storage unit according to an embodiment of the present invention;
7 is a longitudinal sectional view of an ice storage unit according to an embodiment of the present invention.
8 is a control block diagram of a water purifier according to an embodiment of the present invention.
9 and 10 are flowcharts for explaining a control method of a water purifier according to an embodiment of the present invention.

Hereinafter, embodiments will be described in detail with reference to the drawings.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected," "coupled," or "connected. &Quot;

1 is a perspective view of a water purifier according to an embodiment of the present invention.

Referring to FIG. 1, a water purifier 1 according to an embodiment of the present invention includes an outer panel forming an outer shape and a main body 10 covered by the outer panel.

The outer panel may include a front panel 12, a plurality of side panels 11, an upper panel 13, and a bottom panel (not shown). The main body 10 is positioned in a space formed by the panels 11, 12, and 13.

The main body 10 may be provided with an ice discharging part 22 for discharging ice generated in the ice making part to be described later and a water discharging part 20 for discharging water. An ice channel is formed in the ice discharge part 22, and a water channel is formed in the water discharge part 20.

A water receiver (15) is connected to the front lower side of the main body (10). The water receptacle can be located below the ice discharge part 22 and the water discharge part 20. [

The front panel 12 includes a first user interface unit 23 and a second user interface unit 24.

The first user interface unit 23 can input a command related to water or output information. Illustratively, the first user interface unit 23 includes a button for selecting the type of water, an outgoing button for taking out water, and a continuous outgoing button for taking out the water continuously for a predetermined time or taking out a predetermined amount of water However, some of the buttons may be omitted.

When a specific button is selected (pressed or touched), the light emitting unit corresponding to the selected specific button is turned on to emit light By examining, a particular button can act as a display unit. That is, when a specific button is selected, the corresponding light emitting unit is turned on to illuminate the light, so that the user can easily recognize that the specific button has been selected by confirming the light.

The first user interface unit 23 may further include a water level indicator for indicating the water level of the purified water, a water temperature indicator for indicating the temperature of the cold water, and a display unit for indicating the replacement time of the filter. Some of the display portions may be omitted.

The second user interface unit 24 can input a command related to ice or output information. Illustratively, the second user interface unit 24 includes an ice button for selecting ice to be taken out and an ice button for locking or locking the input function (for example, the function of the ice button) of the second user interface unit 24 And a lock button for releasing the lock button.

The second user interface unit 24 may further include a first display unit for informing that ice is being generated in the ice making unit and a second display unit for notifying that the ice making function is canceled. In the present invention, the release of the ice-making function means that ice is not generated in the ice-making part. The ice-making function can be released or selected by a mode selection unit (to be described later), which will be described later.

The second user interface unit 24 may further include a lock display unit for indicating that the input function is locked and an unlock display unit for indicating that the input function is unlocked.

3 is a partial cross-sectional view of a water purifier according to an embodiment of the present invention. FIG. 4 is a perspective view of a water purifier according to an embodiment of the present invention, FIG. 5 is a view illustrating a state in which the ice storage unit is detached from the main body according to an embodiment of the present invention. Referring to FIG.

2 to 5, the main body 10 according to an embodiment of the present invention includes a storage tank 30 in which water filtered by one or more filters is stored, And a cold water tank (not shown) for cooling the water. The storage tank 30 may store normal temperature water.

Depending on the user's selection, the water in the storage tank 30 may be taken out through the water outlet 20 or the water in the cold water tank may be taken out through the water outlet 20. In this embodiment, the main body 10 may not have a cold water tank, but may have a hot water tank, or may have both the cold water tank and the hot water tank. Alternatively, the main body 10 may be provided with at least one of a cold water tank and a hot water tank without the storage tank 30 storing water at room temperature.

The main body 10 is provided in an ice making chamber 40 for generating ice and includes ice making portions 41 and 42 for generating ice and ice stored in the ice making portions 41 and 42, And an ice storage unit 60 detachable from the main body 10.

The ice storage unit 60 is separate from the ice-making units 41 and 42 and may be positioned below the ice-making units 41 and 42.

The ice making chamber 40 may be covered by an ice making chamber cover 43. A part or the whole of the ice making chamber 40 may be formed by the housing 100 and the ice making chamber cover 43 may be connected to the housing 100 so as to open and close the ice making chamber 40.

When the upper panel 13 is detached from the water purifier 1, the ice-making chamber cover 43 may be exposed to the upper side of the main body 10. Then, the user can access the ice-making portions 41 and 42 by opening the ice-making chamber cover 43. [

The ice making sections 41 and 42 may include a cooling section 41 through which a low temperature refrigerant flows and a water storage section 42 in which water is stored. The cooling unit 41 may be, for example, a refrigerant pipe, and a part of the cooling unit 41 may extend downward to be submerged in the water contained in the water storage unit 42. The water stored in the purified water tank 30 may be supplied to the water storage unit 42 or water (filtered water) not passing through the purified water tank 30 may be supplied to the water storage unit 42.

The ice storage unit 60 may be independently insulated in the main body 10. [ That is, the outer surface of the ice storage part 60 may be covered with a heat insulating material. The ice storage portion 60 may be located below the housing forming the ice making chamber 40. [

Or the main body 10 may include a housing 100 in which the ice storage portion 60 is accommodated. The housing 100 may form a receiving space 50 for the ice storage unit 60. The housing 100 may support the ice storage unit 60 to protect the ice storage unit 60 for thermal insulation.

In this embodiment, the housing 100 forms the accommodating space 50 and the ice-making chamber 40, but in the alternative, each of the separate housings may separate the accommodating space 50 and the ice- .

The housing 100 may be provided with an opening 102 through which the ice storage unit 60 can be drawn in and out. The opening 102 may be opened and closed by the opening and closing unit 110.

In the present embodiment, when the front panel 12 is detached from the water purifier 1, the opening / closing part 110 is exposed to the front surface of the main body 10. The user can access the opening and closing part 110 by detaching the front panel 12 and by opening the opening 102 of the housing 100 by operating the opening and closing part 110, The portion 60 can be separated from the main body 10.

The opening / closing part 110 may be rotatably connected to a side of the housing 100 by a hinge. The opening and closing part 110 may be provided with a lever 140 to be fixed to the housing 100 in a state where the opening 102 is closed. The housing 100 is provided with a lever engaging portion 144 for engaging with the lever 140. Accordingly, the user can easily open the opening 102 by releasing the engagement between the lever 140 and the lever engaging portion 144 by operating the lever 140.

The opening and closing part 110 may include an ice inlet 111 through which the ice transferred from the ice storage part 60 flows and an ice outlet 112 through which the ice introduced through the ice inlet 111 is discharged. have. That is, the opening / closing part 110 provides the passage of the ice transferred from the ice storage part 60.

The opening and closing unit 110 may further include a shutter 116 for opening and closing the ice outlet 112 and a shutter driving unit 118 for driving the shutter 116. The shutter 116 may be rotatably connected to the opening and closing part 110. The shutter driving unit 118 may include a motor and a power transmitting unit that transmits the power of the motor to the shutter 116. It is noted that there is no limitation in the shutter drive unit 118 for driving the shutter 116 in the present invention.

The ice discharge portion 22 and the storage chamber 610A of the ice storage portion 60 can be selectively communicated by the operation of the shutter 116 in this embodiment. That is, when the shutter 116 opens the ice outlet 112, the ice discharge unit 22 communicates with the storage chamber 610A of the ice storage unit 60, When the ice outlet 112 is closed, the communication between the ice discharge part 22 and the storage chamber 610A of the ice storage part 60 is cut off.

Specifically, the opening / closing part 110 includes a first body 120 having the ice inlet 111 and the ice outlet 112 formed thereon, and a second body 130 coupled to the first body 120, . As another example, it is possible that the ice body inlet 111 is formed in the first body 120 and the third body in which the ice outlet 112 is formed on the lower side of the first body 120. The lever 140 may be installed on one side of the second body 130.

The main body 10 may further include a heating unit 80 for heating the ice storage unit 60.

The heating unit 80 may be installed in the housing 100 to supply heat to the accommodation space 50 in the housing 100. However, the heating unit 80 may be covered with a heat insulating material (not shown) so that the heat of the heating unit 80 is not supplied to the outside of the inner space of the housing 100.

If there is no ice in the ice storage part 60 in the state that the heating part 80 is on, moisture in the ice storage part 60 or the accommodation space 50 is removed and the ice storage part 60 The ice can be removed after the ice of the ice storage part 60 is melted.

The heating unit 80 may include a heater 810 in the form of a heat ray for generating heat and a fixing sheet 820 for fixing the heater 810 to the housing 100. It is to be noted that there is no limitation in the kind of the heating section 80 in the present invention.

The operation of the heating unit 80 will be described later with reference to the drawings.

FIG. 6 is a perspective view of an ice storage unit according to an embodiment of the present invention, and FIG. 7 is a longitudinal sectional view of an ice storage unit according to an embodiment of the present invention.

Referring to FIGS. 2, 3, 6 and 7, the ice storage unit 60 may include a frame 610 forming a storage chamber 610A for storing ice.

The frame 610 includes a front frame 611 (or a first frame) on which the ice passage 614 is formed and a rear frame 613 Two frames ") and one or more connection frames 615 (or a" third frame ") connecting the front frame 611 and the rear frame 613. Between the front frame 611 and the rear frame 613, a mesh type support part 660 for passing water and supporting the ice can be provided. The frame 610 may include a plurality of connection frames 615 and a support portion 660 may be provided between adjacent two connection frames 616. [

As another example, the frame 610 may include a top opening and a front opening. The upper surface opening serves as a passage through which ice flows into the frame 610, and the front opening serves as a passage through which ice in the frame 610 is discharged. In addition, the frame 610 may have a plurality of holes through which water is discharged.

The ice storage unit 60 may further include an auger 620 for transferring the ice stored in the storage chamber 610A to the ice passage 614 side. However, the auger 620 may be omitted depending on the position or arrangement of the ice storage unit 60. [

The auger 620 may be rotatably supported on the frame 610. [ The auger 620 may include a rotating shaft 622 and a blade 624 extending in a spiral direction from the rotating shaft 622.

A guide rib 626 for guiding the rotation of the auger 620 is formed at a rear end of the rotary shaft 622 and a rotation guide 616 for receiving the guide rib 626 is formed in the rear frame 613. [ . The rotation guide (616) The rear frame 613 may be formed separately from the rear frame 613 and coupled to the rear frame 613 or may be formed integrally with the rear frame 613.

The rotation guide 616 may have a receiving portion for selectively receiving the guide ribs 626. Thus, one side of the auger 620 can be separated from the frame 610. As another example, a protrusion may be formed in the rotation guide 616, and a groove may be formed in the guide rib 626 to receive the protrusion.

The rotation guide 616 not only guides rotation of the auger 610 but also supports one side of the auger 620.

The frame 610 may further include an extension 612 extending forward from the front frame 611. The extended portion 612 may be rounded downward as it goes forward from the front frame 611, for example. The extended portion 612 may be integrally formed with the front frame 611 or may be coupled to the front frame 611.

The extended portion 612 is guided by the auger 620 to guide the ice that has passed through the ice passage 614 to fall downward. To this end, the extension 612 may be rounded outwardly when viewed from the ice passage 614.

At least a part of the extended portion 612 may be inserted into the opening / closing part 110 through the ice inlet 111 of the opening / closing part 110. The ice can be easily dropped to the ice outlet 112 side of the opening and closing part 110 by the extension part 612 as the extended part 612 is positioned in the opening and closing part 110.

The frame 610 is provided with a first guide 63 for guiding the ice dropped from the ice making parts 41 and 42 to drop from the ice storage part 60 to a side close to the ice passage 614 (or the opening of the housing) Member 630 may be provided. The first guide member 630 may be rotatably coupled to the frame 610, for example, to the rear frame 613 by a hinge. The first guide member 630 may include a coupling portion 632 coupled to the frame 610 and an inclined guide portion 640 formed on the coupling portion 632.

The inclined guide portion 640 may be positioned below the vertical portions of the ice making portions 41 and 42. The inclined guide portion 640 may be inclined downward from the rear side toward the front side in a state where the ice storage portion 60 is received in the main body 10. The inclined guide portion 640 may be elastically deformed by an external force. The ice separated from the ice-making portions 41 and 42 is not dropped directly into the frame 610 but falls into the inclined guide portion 640. Therefore, since the ice does not fall off the frame 610, it is possible to prevent the ice from breaking down upon falling of the ice. Even when the ice drops on the inclined guide portion 640, the inclined guide portion 640 can be elastically deformed, so that the impact of ice can be absorbed and the ice can be prevented from being broken.

The engaging portion 632 not only allows the first guide member 630 to be coupled to the frame 610 but also allows the inclined guide portion 640 to be spaced apart from the upper end of the frame 610. As the inclined guide part 640 is spaced apart from the upper end of the frame 610, ice may be positioned below the inclined guide part 640, and the inclined guide part 640 may be positioned below the storage chamber 610A, . That is, not only the storage chamber 610A in the frame 610 but also the space between the frame 610 and the inclined guide unit 640 can store ice.

The inclined guide portion 640 may have at least one hole 642 through which water can pass.

The frame 610 may further include a second guide member 650 for guiding ice stored in the storage chamber 610 to be stored close to the ice passage 614. The second guide member 650 includes an engaging portion 652 coupled to the frame 610 and substantially the connecting frame 615 and an inclined portion 652 formed on the engaging portion 652, And may include a guide portion 654.

The inclined guide portion 654 may be disposed in a space between the auger 620 and the support portion 660. The inclined guide portion 654 may be disposed in the storage chamber 610A and be inclined downward from the rear side toward the front side in a state where the ice storage portion 60 is received in the main body 10. [

In this embodiment, the second guide members 650 may be provided on both sides of the auger 620, but the number of the second guide members 650 is not limited in the present invention.

The main body 10 may further include a driving device 70 for generating power for rotating the auger 620.

The driving unit 70 may include an auger driving unit 710 for generating a driving force and a power transmitting unit 720 and 730 for transmitting the power of the auger driving unit 710 to the auger 620.

The auger driving unit 710 is, for example, a motor and may be installed in the opening / For example, the auger driving unit 710 may be installed in the second body 130 of the opening / closing unit 110. The auger driving unit 710 may be covered by a cover 740 coupled to the opening and closing unit 110.

The power transmission parts 720 and 730 may include a first transmission part 720 provided in the opening and closing part 110 and a second transmission part 730 provided in the ice storage part 60 . The first transmission portion 720 may be connected to the shaft of the motor and the second transmission portion 730 may be connected to the rotation axis 622 of the auger 620.

When the opening and closing part 110 closes the opening 102 of the housing 100, the first transmitting part 720 can be connected to the second transmitting part 730. On the other hand, when the opening and closing part 110 opens the opening 102 of the housing 100, the connection between the first transmitting part 720 and the second transmitting part 730 is released.

The first transducer 720 may be located in a space between the first body 120 and the second body 130. The first transmitting portion 720 may include a first connecting portion 722 connected to the second transmitting portion 730. The first connection portion 722 may be a protrusion, for example, and may penetrate the first body 120. [

The second transfer part 730 may be installed in the extension part 612 of the ice storage part 60. At this time, when the opening and closing part 110 closes the opening 102 of the housing 100 or when the auger driving part 710 is operated while the opening and closing part 110 closes the opening 102, The second transmission portion 730 may be movably installed in the extension portion 612 so that the first transmission portion 720 and the second transmission portion 730 are easily connected. At this time, the second transmission portion 730 may be movable in a direction parallel to the extending direction of the rotation axis 622 of the auger 620.

The extension portion 612 may be provided with an elastic member 740 for elastically supporting the second transmission portion 730. The second transmitting portion 730 is installed in the extended portion 612 by the fixing portion 750.

The second transmission unit 730 may include a second connection unit 732 to which the first connection unit 722 of the first transmission unit 720 is connected. The second connection portion 732 may receive the first connection portion 722. [ That is, it may be a groove for receiving the protrusion. At this time, in order for the power of the driving unit 720 to be stably transmitted to the second transmitting unit 730 through the first transmitting unit 720, the first connecting unit 722 and the second connecting unit 732 The section may be non-circular.

If the first connection portion 722 and the second connection portion 732 are not aligned with each other in the state that the opening and closing portion 110 is closed with the opening 102, Is not connected to the second transmission portion 730 but presses the second transmission portion 730 only. It is needless to say that even when the opening and closing part 110 closes the opening 102 and the first connecting part 722 and the second connecting part 732 are aligned, 2 transmitting portion 730 of the second embodiment. At this time, the first body 120 presses a part of the extended portion 612 so as to prevent the ice storage portion 60 from moving when the opening and closing portion 110 is closed with the opening 102 closed. can do. That is, in the present invention, the opening and closing part 110 can press the ice storage part 60 while the opening and closing part 110 is closed.

When the first transmitting portion 720 presses the second transmitting portion 730, the elastic member 740 is contracted. In this state, when the auger driving unit 710 is operated, the auger driving unit 710 rotates the first transmitting unit 720, but the second transmitting unit 730 does not rotate. If the frictional force of the portion where the first transmission portion 720 and the second transmission portion 730 are in contact with each other is large, the second transmission portion 730 may be rotated when the first transmission portion 720 rotates However, since the rotational force of the first transmitting portion 720 is not completely transmitted to the second transmitting portion 730, the first transmitting portion 720 and the second transmitting portion 730 are relatively rotated.

When the first transmitting portion 720 and the second transmitting portion 730 are rotated relative to each other, the first connecting portion 722 and the second connecting portion 732 are aligned. In this state, The elastic member 740 is pulled.

The elastic force of the elastic member 740 moves the second transmission portion 730 in the direction of approaching the first transmission portion 720 so that the first connection portion 722 and the second connection portion 7320 Respectively.

The second transmission unit 730 may further include a shaft connection part 734 connected to the rotation shaft 622 of the auger 620. The shaft connection portion 734 may be inserted into the rotation axis 622 of the auger 620. As another example, the rotational axis 622 of the auger 620 may be inserted into the shaft connecting portion 734.

Meanwhile, in the housing 100, when the ice stored in the ice storage unit 60 is melted, a discharge port 104 through which molten water is discharged may be formed. The discharge port 104 is connected to the discharge pipe 106 and is discharged to the outside of the water purifier 1 along the discharge pipe 106.

8 is a control block diagram of a water purifier according to an embodiment of the present invention.

3, 6, and 8, the water purifier 1 of the present embodiment includes a temperature sensor 26 for detecting a room temperature, and a temperature sensor 26 provided in the main body 10, A mode selection unit 27 for opening or closing the opening 102 of the ice storage unit 60 or opening and closing the opening 102 of the ice storage unit 60, A heater 810 for heating the interior space of the housing 100, a cooler 90 for generating ice, and a controller 25 for various controls can do.

The mode selector 27 may be provided on the rear side of the main body 10 as an example. The mode selection unit 27 may be an on-off switch, but it is to be noted that there is no limitation on the type of the mode selection unit 27.

The cooler 90 may include a compressor, a condenser, and an expander for forming the refrigerant cycle with the above-described ice making units 41 and 42.

When the ice-making function is turned on by the mode selecting unit 27, ice is generated in the ice-making units 41 and 42.

The ice produced in the ice-making portions 41 and 42 is separated from the ice-making portions 41 and 42 and falls downward. The ice dropped in the ice making parts 41 and 42 is dropped onto the first guide member 630 and then moved along the first guide member 630 and flows into the ice storage part 60.

Ice is constantly generated in the ice making units 41 and 42 unless ice-fullness is detected by the ice-making sensor 28. In the present invention, the method for sensing the full ice and the type of the sensor can be implemented by a known structure, and thus a detailed description thereof will be omitted.

The temperature sensor 26 may be installed in a front portion of the main body 10. For example, the temperature sensor 26 may be installed on the front panel 12. When the temperature sensor 26 is installed on the front panel 12, the influence of the internal components of the main body 10 on the temperature is minimized, so that the room temperature can be accurately measured.

The user can input the ice discharge command through the second user interface unit 24 for taking out the ice.

When the ice discharge command is inputted, it is detected by the opening / closing detector 29 whether or not the opening 102 is closed by the opening / closing part 110. If the opening 102 is not completely closed, the auger 620 is not rotated even if the auger driving unit 710 is driven. In this case, even if the ice discharge command is input, no ice is discharged, so that the user can recognize that the water purifier 1 is malfunctioning. Therefore, in the present invention, when the ice discharge command is inputted, if the closing of the opening 102 is not detected, the second user interface unit 24 displays information for notifying the inspection (the opening is opened) can do.

On the other hand, when the ice discharge command is input, when the opening of the opening 102 is detected, the controller 36 turns on the auger driving unit 720. Then, the auger driving unit 720 is turned on and the power of the driving unit 720 is transmitted to the auger 620 through the first transmitting unit 720 and the second transmitting unit 730. Then, the auger 620 is rotated, and the ice stored in the storage chamber 610A is transferred to the ice passage 614 by the auger 620. In addition, the shutter driving unit 118 operates to open the ice outlet 116 of the opening / closing unit 110 by the shutter 116. [

The ice moved to the ice passage 614 is guided by the extended portion 612 and falls to the ice outlet 112 side. Then, the ice is eventually discharged to the outside through the ice discharger 22.

Meanwhile, in order to separate the ice storage unit 60, the front panel 12 is detached from the main body 10. Then, the opening / closing part 110 is exposed to the front surface of the main body 10.

Then, the lever 140 of the opening / closing part 110 is operated to release the engagement between the lever 140 and the lever coupling part 144. Then, the opening and closing part 110 can open the opening 102 of the housing 100. The user can open the opening 102 of the housing 100 by rotating the opening and closing part 110.

Then, when the opening / closing part 110 opens the opening 102 of the housing 100, the ice storage part 60 is exposed to the outside. For example, the extension of the ice storage part 160 is exposed to the outside. Then, the user can finally take out the ice storage portion 160 from the main body 10. [

According to the present invention, since the user can easily separate the ice storage unit 60 from the main body 10, the ice storage unit 60 can be easily cleaned.

In addition, there is an advantage that the accommodation space 50 of the housing 100 can be cleaned while the ice storage unit 60 is separated.

9 and 10 are flowcharts for explaining a control method of a water purifier according to an embodiment of the present invention.

Referring to FIG. 9, the controller 25 determines whether the ice-making function is turned off during the ice-making operation. As described above, the ice-making function can be turned off by the mode selecting unit 27. [

If it is determined that the ice-making function is off, the temperature sensor 26 senses the room temperature (S2). Of course, the temperature sensor 26 may periodically sense the temperature, and the controller 25 may periodically acquire the room temperature sensed by the temperature sensor 26. [

When the ice-making function is turned off, the ice-making is stopped when the ice-making portions (41, 42) are in ice-making.

The control unit 25 determines the on-reference time of the heater 810 based on the temperature sensed by the temperature sensor 26 (S3). Then, the controller 25 turns on the heater 810 (S4). In the present invention, when the ice making function is turned off, the heater 810 is turned on to dry the space inside the ice storage unit 60 and the housing 100.

The on-reference time of the heater 810 according to the temperature sensed by the temperature sensor 26 may be stored in a memory (not shown). For example, when the temperature sensed by the temperature sensor 26 is lower than a first reference temperature (for example, 10 degrees), the on reference time of the heater 810 is set to a first reference time (for example, 12 hours) Can be set. When the temperature detected by the temperature sensor 26 is equal to or higher than the first reference temperature and lower than the second reference temperature (for example, 20 degrees), the on reference time of the heater 810 is set to a second reference time For example 9 hours). When the temperature sensed by the temperature sensor 26 is equal to or higher than the second reference temperature, the on-reference time of the heater 810 may be set to a third reference time (e.g., 6 hours).

That is, the higher the room temperature, the easier the drying of water. Thus, in the present invention, the warm-up time of the heater 810 is set to be lower as the room temperature is higher.

In the above description, the ON reference time of the heater 810 is set to three, but it is also possible that the heater 810 is turned on for a predetermined time regardless of the room temperature. It is to be noted that the number of ON reference times of the heater 810 according to the room temperature is not limited.

When the heater 810 is turned on, a timer (not shown) or the control unit 25 counts the ON time of the heater 810.

When the heater 810 is turned on, heat is supplied into the housing 100. When ice is present in the ice storage part 60, the ice in the ice storage part 60 is melted by the heat supplied into the housing 100, and the melted water is discharged to the discharge port 104 of the housing 100, . When the on time of the heater 810 is increased, the ice of the ice storage part 60 is completely melted and moisture can be completely removed. The moisture in the ice storage part 60 and the moisture in the housing 100 can be completely removed by the heater 810 when no ice is present in the ice storage part 60. [

When the heat is continuously supplied to the housing 100, the pressure of the housing 100 is increased and the amount of steam in the housing 100 is increased, so that the steam in the housing 100 must be discharged. The shutter driving unit 118 is turned on and off one or more times while the heater 810 is turned on to discharge the steam in the housing 100. [ For example, the shutter driving unit 118 can repeatedly turn on / off intermittently, so that the shutter 116 can be intermittently opened and closed (S5).

The shutter 116 opens the ice outlet 112 of the opening and closing part 110 by turning on the shutter driving part 118 so that the ice discharge part 22 and the accommodation space 50 of the housing 100 . Accordingly, the steam in the housing 100 can be discharged to the outside of the water purifier 1 through the ice discharger 22.

The control unit 25 determines whether the on-time of the heater 810 has reached the on-reference time (S6). When the ON time of the heater 810 reaches the ON reference time, the controller 25 turns off the heater 810 (S7).

According to the present invention, when the ice making function is turned off, the heater is turned on to dry the ice storage unit and the inside of the housing, so that bacteria and molds can be prevented from living in the ice storage unit or the housing .

In the above description, since the heater 810 is turned on when the ice-making function is turned off, the step of determining whether the ice-making function is turned off (step S2) includes a step of determining whether the operating condition of the heater can do.

The heater 810 is turned on when the ice making function is selected by the mode selecting unit 27 before the heater 810 is turned on and the on time of the heater 810 reaches the on time reference time Off.

On the other hand, if it is determined in step S1 that the ice-making function is not turned off, the ice-making function is continuously performed (S11). The room temperature is sensed by the temperature sensor 26 (S12). Of course, the temperature sensor 26 may periodically sense the temperature, and the controller 25 may periodically acquire the room temperature sensed by the temperature sensor 26. [

The control unit 25 determines whether the room temperature sensed by the temperature sensor 26 is lower than a reference room temperature (S13) (comparing the sensed room temperature with the reference room temperature). If it is determined in step S13 that the sensed room temperature exceeds the reference room temperature, the process returns to step S1.

On the other hand, if the sensed room temperature is lower than the reference room temperature, the controller 25 turns on the heater 810 (S14). In the present invention, the reference room temperature may be, for example, 5 degrees.

When the room temperature is lower than the reference room temperature, the ice stored in the ice storage unit 60 is entangled with each other. In this case, even if the user inputs an ice discharge command, the ice is not discharged from the ice storage unit 60, or the ice storage unit is broken by the ice, or the ice is inadvertently broken by the friction with the auger, There is a problem of ice discharge. In this case, it can be recognized that the user's emotional complaint is caused or the water purifier is broken.

Accordingly, in the present invention, when the room temperature is lower than the reference room temperature, the heater 810 is turned on to melt the ice in the ice storage unit 60.

When the heater 810 is turned on, the ice making in the ice making parts 41 and 42 is stopped (S15). In the present invention, stopping of ice-making is different from turning off the ice-making function, which means that the ice-making function is on but the ice-making is in the waiting state.

While the heater 810 is turned on, the shutter driving unit 118 may be turned off after being turned on at least once. For example, the shutter driving unit 118 can repeatedly turn on and off intermittently, and the shutter can be intermittently opened and closed (S16).

The shutter 116 opens the ice outlet 112 of the opening and closing part 110 by turning on the shutter driving part 118 so that the ice discharge part 22 and the accommodation space 50 of the housing 100 . Accordingly, the steam in the housing 100 can be discharged to the outside of the water purifier 1 through the ice discharger 22.

Next, during the operation of the heater 810, the controller 25 determines again whether or not the sensed room temperature exceeds the reference room temperature (S17).

If it is determined in step S17 that the sensed room temperature does not exceed the reference room temperature, the control unit 25 determines whether the on-time of the heater 810 has reached the on-reference time (eg, 12 hours) (S18).

The on-reference time may be a time required for the ice to melt and completely dry when there is ice in the ice storage unit 60, for example, 12 hours. The size of the ice storage unit, And the like.

If it is determined in step S18 that the on-time of the heater 810 has not reached the on-reference time, the process returns to step S14. On the other hand, if it is determined that the ON time of the heater 810 has reached the ON reference time, the controller 25 turns off the heater (S19).

When the heater 810 is turned off, the controller 25 determines again whether the sensed room temperature exceeds the reference room temperature (S20).

If it is determined in step S20 that the sensed room temperature exceeds the reference room temperature, the process returns to step S1. Therefore, as long as the ice-making function is not turned off, the ice-making in the ice-making sections 41 and 42 is started.

On the other hand, if it is determined in step S20 that the sensed room temperature does not exceed the reference room temperature, the process returns to step S19. That is, even if the heater 810 is turned off, if the sensed room temperature does not exceed the reference room temperature, there is a high likelihood that the ice will be re-entrapped even if ice is generated in the ice-making unit 41. Therefore, If the sensed room temperature does not exceed the reference room temperature after the heater 810 is turned off, the ice-making sections 41 and 42 maintain the ice-making standby state (ice-making stop state).

On the other hand, if it is determined in step S17 that the sensed room temperature exceeds the reference room temperature, the controller 25 turns off the heater 810 (S21). That is, the controller 25 turns off the heater 810 when the sensed room temperature exceeds the reference room temperature even if the on-time of the heater does not reach the on-reference time.

In the above embodiment, the process of melting the ice in the ice storage unit with the heater turned on can be referred to as an ice melting process. At this time, the ice-making process may be performed automatically, and information for notifying the ice-making process may be displayed on the second user interface unit 24.

In the above description, since the heater 810 is turned on when the sensed room temperature is lower than the reference room temperature, step S13 of comparing the sensed room temperature with the reference room temperature is performed so that the operating condition of the heater It can be said that it is a step of judging whether or not it is.

A configuration in which the support portion 60 is omitted from the ice storage portion 60 may be referred to as auger assembly. In this case, ice may be stored in the auger assembly or stored in the bottom of the receiving space 50. [

As another example, in the above embodiment, the opening and closing part is connected to the housing to open and close the opening of the housing. Alternatively, the opening and closing part may be provided on the external panel. In this case, the ice storage unit (or the auger assembly) can be taken out from the water purifier by operating the opening / closing unit without separating one panel constituting the external panel from the water purifier.

10: main body 20: water discharge part
22; An ice discharge part 60; Ice storage
80:

Claims (18)

A body having a filter;
A ice making unit for generating ice by receiving purified water by a filter of the main body;
An ice storage part for storing the ice produced in the ice making part;
An ice discharge unit provided in the main body and through which the ice stored in the ice storage unit is taken out;
A heating unit for heating the ice storage unit; And
And a shutter for selectively communicating the ice discharger and the ice reservoir,
Wherein the shutter is opened at least once before the heating unit is turned on and off. The method according to claim 1,
Further comprising a mode selection unit for turning on or off the ice making function,
And the heating unit is turned on when the ice-making function is turned off by the mode selection unit. 3. The method of claim 2,
And the heating unit is turned off when the heating unit is turned on and the reference time has elapsed. A body having a filter;
A temperature sensor provided in the main body for sensing a room temperature;
A ice making unit for generating ice by receiving purified water by a filter of the main body;
An ice storage part for storing the ice produced in the ice making part;
An ice discharge unit provided in the main body and through which the ice stored in the ice storage unit is taken out; And
And a heating unit for heating the ice storage unit,
When the operating condition of the heating unit is satisfied, the heating unit is operated,
And the on-reference time is set differently according to the room temperature sensed by the temperature sensor when the heating unit operates. The method of claim 3,
Wherein the heating unit is turned off when the ice-making function is turned on by the mode selecting unit before the reference time elapses from the heating unit being turned on. The method of claim 3,
Further comprising a temperature sensor provided in the main body for sensing a room temperature,
And the on-reference time of the heating unit is set differently according to the room temperature sensed by the temperature sensor. A body having a filter;
A temperature sensor provided in the main body for sensing a room temperature;
A ice making unit for generating ice by receiving purified water by a filter of the main body;
An ice storage part for storing the ice produced in the ice making part;
An ice discharge unit provided in the main body and through which the ice stored in the ice storage unit is taken out; And
And a heating unit for heating the ice storage unit,
Wherein the heating unit is turned on when the room temperature sensed by the temperature sensor is lower than a reference temperature. delete 8. The method according to claim 4 or 7,
Further comprising a shutter for selectively communicating the ice discharger and the ice reservoir,
And the shutter is opened or closed at least once after the heating unit is turned on. 8. The method of claim 7,
And the heating unit is turned off when the room temperature detected by the temperature sensor exceeds the reference temperature after the heating unit is turned on. 11. The method of claim 10,
If the room temperature detected by the temperature sensor does not exceed the reference temperature after the heating unit is turned on, it is determined whether the ON time of the heating unit has passed the reference time,
And the heating unit is turned off when it is determined that the ON time of the heating unit has passed the reference time. 12. The method of claim 11,
Wherein the ice maker maintains the ice-making state in the ice-making section until the room temperature sensed by the temperature sensor exceeds the reference temperature after the heating section is turned off. The method according to any one of claims 1, 4, and 7,
Further comprising a housing surrounding the ice reservoir,
And the heating unit is installed in the housing. The ice-making function is turned on;
Wherein the operating condition of the heating unit is satisfied when the ice making function is turned on;
Heating the ice reservoir to store the ice when the heating unit is satisfied; And
And opening the shutters for selectively communicating the ice discharge unit and the ice storage unit at least once to discharge the steam before the heating unit is turned off. 15. The method of claim 14,
Wherein when the operating condition of the heating unit is satisfied, the ice making function is turned off through the input unit, or the room temperature sensed by the temperature sensor is below the reference temperature. 16. The method of claim 15,
Wherein the heating unit is turned on and the heating unit is turned off when a predetermined time elapses. 16. The method of claim 15,
Wherein the heating unit is turned off when the ice-making function is turned on after the ice-making function is turned off and the heating unit is turned on. 16. The method of claim 15,
Wherein the heating unit is turned off when the indoor temperature detected by the temperature sensor exceeds the reference temperature after the indoor temperature detected by the temperature sensor is lower than the reference temperature and the heating unit is turned on.

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