KR20160053888A - Water purifing apparatus and control method thereof - Google Patents

Abstract

The present invention relates to a water treatment apparatus, and a control method thereof. According to one preferred embodiment of the present invention, a water treatment apparatus comprises: a cooling tank for accommodating a cooling medium therein; a cooling unit accommodated in the cooling tank to cool the cooling medium; a coolant flow path installed on a lower part of the cooling unit to be spaced apart from the cooling unit while passing through the cooling tank, and cooled through the cooling medium; ice detection units installed to have different distances to the cooling unit to detect ice which grows in the cooling unit; an input unit for determining the number of the ice detection units for detecting ice; a control unit for stopping or operating the cooling unit by determining whether ice is detected or not by the ice detection units of the number predetermined by the input unit; and a display unit for displaying the temperature of cool water which is capable of being reached by the ice detection units predetermined by the input unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a water treatment apparatus,

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

Generally, a water treatment device is a device that allows water to be filtered for drinking. The water treatment apparatus includes a water purifier, an ionizer, and a refrigerator capable of extracting purified water.

The water treatment device may be provided with a cooling device for cooling the purified water. The cooling device includes an evaporator for cooling the cooling water accommodated in the cooling tank, a temperature sensor for measuring the temperature of the cooling water cooled by the evaporator, and a cooling pipe that is cooled by the cooling water while passing through the cooling tank.

At this time, the cooling device causes the ice to be frozen on the surface of the evaporator, and the cool air accumulated in the ice is transferred to the cooling pipe through the cooling water. In addition, the cooling device controls the temperature of the cold water by supplying and blocking the refrigerant to the evaporator according to the temperature sensed by the temperature sensor.

However, in the conventional water treatment apparatus, when the ice on the surface of the evaporator grows up to the temperature sensor, the resistance increases infinitely so that the temperature can not be normally measured. Further, when the purified water of the cooling pipe is frozen due to the continuous operation of the evaporator, it is difficult for the cooling device to perform the cooling function normally.

In order to solve the above problems, an object of the present invention is to provide a water treatment apparatus capable of controlling the temperature of cold water by detecting the growth of ice and a control method thereof.

Another object of the present invention is to provide a water treatment apparatus and a control method thereof that can control the temperature of cold water even if ice is grown up to the ice sensing unit.

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

A water treatment apparatus according to a preferred embodiment of the present invention includes a cooling tank in which a cooling medium is received, a cooling unit accommodated in the cooling tank to cool the cooling medium, A plurality of cooling water flow paths provided at a lower portion of the cooling unit and spaced apart from the cooling unit so as to be spaced apart from each other and to detect ice growing in the cooling unit; And an ice detection unit for detecting the ice, and an input unit for setting the number of ice detection units for detecting ice, and a control unit for determining whether ice is detected in a predetermined number of ice detection units through the input unit, A control unit; And a display unit for displaying the temperature of the cold water that can be achieved by the ice detection unit set by the input unit.

Preferably, the control unit may operate the cooling unit such that the number of ice sensing units sensing ice growing in the cooling unit is at least equal to the number of ice sensing units preset by the input unit.

Further, preferably, the cooling tank may further include a stirrer to stir the cooling medium.

Preferably, the display unit may display the number of ice detection units that can be set through the input unit.

On the other hand, the present invention as another aspect provides a method of controlling a water treatment apparatus.

A control method of a water treatment apparatus according to the present invention includes: a step of operating a cooling unit; And controlling the temperature by stopping the operation of the cooling unit when the number of ice sensing units for sensing the ice growing in the cooling unit reaches a predetermined number.

Preferably, in the step of controlling the temperature, the cooling unit may be operated so that the number of ice sensing units sensing ice is at least equal to the number of predetermined ice sensing units.

More preferably, in the step of operating the cooling unit, the stirrer may be operated to circulate the cooling medium.

According to the present invention, the temperature of cold water can be controlled by detecting ice.

Further, even if ice is grown up to the ice sensing unit, the temperature of the cold water can be controlled.

1 is a perspective view of a water treatment apparatus cooling apparatus according to the present invention.
2 is a sectional view of a temperature measuring device and a cooling unit of the water treatment apparatus of FIG.
3 is a conceptual diagram of a water treatment apparatus control method according to the present invention.

To achieve the above object, a water treatment apparatus and a control method thereof according to the present invention will be described.

FIG. 1 is a perspective view of a cooling apparatus of a water treatment apparatus according to the present invention, and FIG. 2 is a sectional view of a temperature measurement apparatus and a cooling unit of the water treatment apparatus.

Referring to FIGS. 1 and 2, the water treatment apparatus includes a cooling device 101 for cooling filtered water in a filter unit (not shown). The cooling device 101 may include a cooling tank 110, a cooling unit 120, a cooling water passage unit 120, and a plurality of ice sensing units 141 and 145.

A cooling medium is accommodated in the cooling tank 110. As the cooling medium, water capable of transmitting cold air to the cooling water channel portion 130 may be applied.

The cooling unit 120 is accommodated in the cooling tank 110 to cool the cooling medium. The cooling unit 120 may be an evaporator constituting a refrigerant system. At this time, the cooling unit 120 may be formed by winding the refrigerant pipe of the evaporator several times in a rectangular shape.

The refrigerant system generates cold air in the evaporator by circulating the refrigerant along a compressor (not shown), a condenser (not shown), an expansion valve (not shown) and an evaporator.

The cooling water channel portion 130 is installed to pass through the cooling tank 110 and is cooled through the cooling medium. At this time, the cooling water channel portion 130 may be formed by winding the cooling water pipe several times. Therefore, the cold water flows continuously in the cooling water passage portion 130 without stagnation.

The cooling water channel portion 130 may be disposed below the cooling unit 120 at a predetermined interval. At this time, since the cooling air of the cooling unit 120 is moved to the lower side of the cooling unit 120 because the temperature is relatively low, the cooling medium below the cooling unit 120 is relatively lower in temperature than the cooling medium on the upper side do. Therefore, the cool air of the cooling unit 120 can be more easily transmitted to the cooling water flow path portion 130.

The plurality of ice sensing units 141 and 145 are installed at different distances from the cooling unit 120. FIG. 2 shows a case where two ice detection units 141 and 145 are installed.

Each of the ice sensing units 141 and 145 senses the ice 125 according to the thickness of the ice growing in the cooling unit 120. That is, the ice sensing unit 141 near the cooling unit 120 senses ice when the thickness of the ice 125 is not relatively thick, and detects the ice when the thickness of the ice 125 is not relatively large. Detects ice when the thickness of the ice 125 is relatively thick. In FIG. 2, a dotted line shows an ice region grown in the cooling unit 120.

Each of the ice sensing units 141 and 145 may include a pair of ice sensing rods 142 and 146. Each of the ice sensing units 141 and 145 supplies a voltage to the pair of ice sensing rods 142 and 146 to measure the resistance of the pair of ice sensing rods 142 and 146 to measure the ice 125.

At this time, when ice does not freeze on the ice sensing rods 142 and 146 of the ice sensing units 141 and 145 (water is contacted), a current flows between the ice sensing rods 142 and 146.

When the ice 125 is frozen in the ice detection rods 142 and 146 of the ice detection units 141 and 145, the resistance of each of the ice detection units 141 and 145 becomes infinite. Therefore, current does not flow between the ice detection rods 142 and 146. FIG.

Thus, it is possible to determine whether the ice 125 has frozen by sensing whether current flows through the ice detection rods 142 and 146 of the ice detection units 141 and 145. [

The cooling device 101 may further include a stirrer 150 to stir the cooling medium. The stirrer 150 may include a stirring fan 151 for stirring the cooling medium and a motor 152 for rotating the stirring fan 151.

Each of the ice sensing units 141 and 145 may be electrically connected to the control unit 161 and the control unit 161 may be electrically connected to the input unit 163 of the water treatment equipment. Also, the display unit 165 may be electrically connected to the controller 161.

The display unit 165 displays ice sensing units 141 and 145 that can be input.

The user can set the ice detection units 141 and 145 through the input unit 163 while viewing the display unit 165. [

For example, if the user desires cold water at a relatively low temperature (approximately 4 ° C), the user can select two ice detection units 141 and 145 through the input unit 163. In addition, when the user desires cold water at a relatively high temperature (approximately 10 ° C), one ice sensor 141 can be selected through the input unit 163. If three or more ice sensing units 141 and 145 are installed, a relatively large number of ice sensing units 141 and 145 may be selected if a relatively low cold water temperature is desired.

At this time, the temperature of the predetermined cold water may be displayed on the display unit 165 according to the number of the ice sensing units 141 and 145 set through the input unit 163. [ For example, when two ice detection sections 141 and 145 are selected, a cold water temperature of 4 ° C is displayed. When one ice sensing section 141 is selected, a cold water temperature of 10 ° C is displayed.

Thus, the user can see how the cold water temperature has been set by looking at the display unit 165.

The control unit 161 stops the cooling unit 120 when the ice 125 is detected by the ice detection units 141 and 145 through the input unit 163. [ The control unit 161 activates the cooling unit 120 when ice 125 is not sensed by all of the predetermined ice sensing units 141 and 145 (when water is sensed).

The control unit 161 determines whether or not the ice 125 is sensed by the predetermined ice sensing units 141 and 145 and controls the temperature of the cooling unit 101 by stopping and operating the cooling unit 120.

A control method of the water treatment apparatus according to the present invention constructed as described above will now be described. The following description is based on the case where two ice sensing units are installed.

3 is a conceptual diagram of a control method of a water treatment apparatus according to the present invention.

Referring to FIG. 3, the user pre-sets the number of ice detection units 141 and 145 through an input unit 163 (S11).

For example, if the user desires a cold water temperature of approximately 10 ° C, one ice sensing unit 141 near the cooling unit 120 is set. In addition, when the user desires a cold water temperature of about 4 캜, two ice detection units 141 and 145 are set. Of course, when three or more ice detection units 141 and 145 are installed, the user can select and vary the cold water temperature.

At this time, the temperature of the cold water is displayed on the display unit 165 according to the number of the ice sensing units 141 and 145 selected by the user. That is, when one ice sensing unit 141 is set, a cold water temperature of 10 ° C is displayed, and when two ice sensing units 141 and 145 are set, a cold water temperature of 4 ° C can be displayed.

After the ice detection units 141 and 145 are set as described above, the cooling mode is selected by pressing the cooling mode button through the input unit 163 (S12).

Subsequently, as the cooling unit 120 is operated, low-temperature refrigerant flows along the cooling unit 120 (S13). At this time, the cooling medium in the cooling unit 120 is cooled by the heat exchange between the cooling medium and the cooling medium.

In addition, the stirrer 150 is operated to circulate the cooling medium in the cooling tank 110 (S14). Therefore, the heat exchange efficiency between the cooling air of the cooling unit 120 and the cooling medium is improved.

The cooling medium transfers cold air to the purified water passage 130, thereby generating cold water.

By the action of the cooling unit 120 as described above, the cooling medium is gradually cooled to a low temperature.

As the temperature of the cooling medium gradually decreases, the ice 125 is grown on the surface of the cooling unit 120.

As the ice 125 gradually grows, the ice 125 of the cooling unit 120 is grown up to the ice detection units 141 and 145. [

The control unit 161 determines whether ice 125 is detected by the ice detection units 141 and 145 at step S15.

For example, when the user selects one of the ice detection units 141 and 145 through the input unit 163, if the ice detection unit 141 detects the ice 125, the control unit 161 determines that the temperature of the cold water It is determined that the target temperature has been reached.

When the two ice detection units 141 and 145 are selected through the input unit 163 and only when the ice 125 is detected by the two ice detection units 141 and 145, It is judged that the temperature has been reached. At this time, the controller 161 does not determine that the temperature of the cold water has reached the target temperature even if the ice 125 is detected by one ice detector 141.

If it is determined that the ice 125 is detected in the ice detection units 141 and 145 preset in the control unit 161, the cooling unit 120 is stopped (S16). At this time, the cooling unit 120 stops the flow of the refrigerant.

Even if the cooling unit 120 is stopped, the cool air accumulated in the ice 125 is continuously supplied to the cooling medium. Accordingly, the cooling medium is continuously supplied with cold air while the ice 125 is frozen. Also, the ice of the cooling unit 120 gradually melts over time.

The control unit 161 determines whether ice 125 is detected in the ice detection units 141 and 145 (S17). That is, it is determined whether water is sensed by the predetermined ice sensing units 141 and 145.

At this time, when two ice detection units 141 and 145 are set, the control unit 161 determines that the ice 125 is not detected only when the ice 125 is melted by the two ice detection units 141 and 145. Otherwise, when the ice 125 is melted only in one of the two ice detection units 141 and 145, it is determined that the ice 125 is being sensed.

If it is determined that the ice 125 is not detected in the predetermined ice sensing units 141 and 145, the cooling unit 120 is operated again to cool the cooling medium (S18). That is, when it is determined that water has been sensed by the predetermined ice sensing units 141 and 145, the cooling unit 120 is operated.

As described above, the temperature of the cold water can be adjusted as desired according to the number of the predetermined ice sensing units 141 and 145. Therefore, even if ice is frozen in the ice sensing units 141 and 145, the temperature of the cold water can be controlled.

101: cooling device 110: cooling tank
120: cooling unit 130: cooling water channel part
141, 145: ice sensing part 150: stirrer
161: control unit 163:

Claims (7)

A cooling tank in which a cooling medium is accommodated;
A cooling unit accommodated in the cooling tank to cool the cooling medium;
A cooling water channel portion that is passed through the cooling tank and installed at a lower portion of the cooling unit so as to be spaced apart from the cooling unit and cooled through the cooling medium;
A plurality of ice sensing units installed at different distances from the cooling unit to sense ice growing in the cooling unit;
An input unit for setting the number of ice sensing units for sensing ice;
A control unit for determining whether ice is detected in a predetermined number of ice sensing units through the input unit and stopping or activating the cooling unit; And
A display unit for displaying the temperature of the cold water that can be achieved by the ice detection unit set by the input unit;
.
The method according to claim 1,
Wherein,
Wherein the cooling unit is operated such that the number of ice sensing units sensing ice growing in the cooling unit is at least equal to the number of ice sensing units preset by the input unit.
The method according to claim 1,
Wherein the cooling tank further includes an agitator for agitating the cooling medium.
The method according to claim 1,
The display unit includes:
And displays the number of ice detection units that can be set through the input unit.
Operating the cooling unit; And
And controlling the temperature by stopping the operation of the cooling unit when the number of ice sensing units for sensing ice growing in the cooling unit reaches a predetermined number.
6. The method of claim 5,
In the step of controlling the temperature,
Wherein the cooling unit is operated so that the number of ice detecting units detecting ice is at least equal to the number of predetermined ice detecting units.
The method according to claim 6,
In the step of operating the cooling unit,
And the agitator is operated to circulate the cooling medium.

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