KR101127921B1 - Method of sensing ice-making tray attached or detached to water purifier having ice-maker - Google Patents

Abstract

The present invention relates to a desorption detection method of ice trays for ice water purifiers for determining the desorption of ice trays, and in particular, the desorption detection method of ice trays for ice water purifiers according to the present invention, accommodated in the ice trays rotatably configured A method of detecting desorption of ice trays for ice water purifiers for cooling water by an ice maker evaporator, the method comprising: detecting a temperature of an ice maker evaporator after a predetermined time elapses from an ice maker system (ON); Comparing with a reference temperature; Determining that the ice tray is not mounted when the sensed temperature is lower than the reference temperature; And stopping the ice making system when it is determined that the ice tray is not mounted, thereby stopping the ice making system that generates ice when the ice tray is not mounted in the ice making process. Breakage can be prevented.

Ice Maker Evaporator, Reference Temperature

Description

Method for sensing ice-making tray attached or detached to water purifier having ice-maker}

The present invention relates to a method for detecting desorption of ice trays for ice water purifiers for determining the desorption of ice trays.

In general, ice water purifier is a device for supplying purified water, cold water, hot water and ice to the user by purifying raw water, such as tap water. An ice water purifier typically includes a filter unit for purifying raw water, a purified water tank for storing purified water, a cold water tank for cooling purified water, an ice making unit for making ice, and a hot water tank for heating and storing purified water. It can be provided as.

As such, the ice water purifier produces ice by immersing an ice making evaporator in raw ice water contained in an ice making drip tray, and then defrosting by rotating a water holding drip tray by driving a motor. Then, the frozen ice is used to generate cold water.

However, the ice trays are combined with a rotating structure inside the ice water purifier so that they easily fall off when an external shock is applied. As described above, when the ice making drip tray is subjected to the ice making process in a non-mounted state separated by an impact, the ice making evaporator provided in the ice making unit may be damaged.

The present invention provides a method for detecting desorption of ice trays for ice water purifiers that can determine the desorption state of the ice trays by comparing the temperature of the ice making evaporator with a predetermined reference temperature after a predetermined time has elapsed from the deicing process on. There is a purpose.

In the ice water purifier desorption detection method for ice water purifier according to the present invention, in the ice water purifier desorption detection method for ice water purifier to cool the water contained in the ice storage drip tray rotatably configured by the ice making evaporator, the ice making system on Detecting a temperature of the ice-making evaporator after a predetermined time elapses from the predetermined time, and comparing the detected temperature with a preset reference temperature; Determining that the ice tray is not mounted when the sensed temperature is lower than the reference temperature; And stopping the ice making system when it is determined that the drip tray for ice making is not mounted.

In addition, detecting the temperature of the ice making evaporator may detect the temperature of the refrigerant at the outlet side of the ice making evaporator.

In addition, the reference temperature may add a predetermined value to the temperature of the refrigerant at the outlet side of the ice making evaporator after a predetermined time elapses from the ice making system on according to the temperature inside the ice purifier in the state where the ice making drip tray is not installed. .

The method may further include indicating that the ice tray is not mounted when it is determined that the ice tray is not mounted.

The method may further include performing an ice making process when the sensed temperature exceeds the reference temperature and rotating the ice tray to remove the ice.

Desorption detection method for the ice water purifier for ice water purifier according to the present invention is to determine the desorption state of the ice tray drip tray to prevent the de-icing process in the unmounted state of the ice tray drip tray, and also to prevent the breakage of the ice maker evaporator.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In addition, the present embodiment is not intended to limit the scope of the present invention, but is presented by way of example only, and various modifications may be made without departing from the technical gist of the present invention.

1 is a schematic view showing the internal structure of the ice purifier according to the present invention, Figure 2 is a perspective view showing an ice making unit provided in the ice purifier according to the present invention.

1 or 2, the ice purifier 100 according to the present invention is a purified water tank 10 for storing purified water, a cold water tank 20 for cooling the water contained therein, and the purified water tank ( 10) or an ice making unit 30 for receiving ice from the cold water tank 20 to generate ice, an ice storage 40 for storing ice generated in the ice making unit 30, and the ice making unit 30 It may be configured to include a guide member 50 for guiding the ice generated in the cold water tank 20 or the ice reservoir 40 to be selectively supplied.

The purified water tank 10 is to accommodate the water filtered through the filter unit (not shown), and has a configuration similar to that used in a conventional water purifier, so a detailed description thereof will be omitted.

The cold water tank 20 receives water from the purified water tank 10 and cools the water contained therein by using the ice generated through the ice making unit 30. In addition, a temperature sensor (not shown) for detecting the water temperature may be installed in the cold water tank 20. The water temperature in the cold water tank 20 is controlled by supplying the ice generated in the ice making unit 30 to the cold water tank 20.

The ice making unit 30 forms a cooling cycle similar to that provided in a conventional cooling device. In addition, the ice making unit 30 may include an ice making evaporator 31 and an ice making drip tray 33 that receives the purified water, that is, a first drip tray 34 and a second drip tray 35. .

The ice making unit 30 is to be immersed in the raw water for deicing water accommodated in the first drip tray 34 provided in the ice receiving drip tray 33 is the immersion pipe 32 provided in the ice making evaporator 31 of the cooling cycle. In addition, although the raw water for ice making may be cooled according to the operation of the ice making unit 30, an immersion type ice making method may be employed in which ice is formed around the immersion tube 32, but the present invention is not limited thereto. And a deicing method can be applied.

In addition, a temperature sensor 38 for measuring the temperature of the refrigerant may be installed at the outlet side of the ice making evaporator after generating ice through an immersion tube. The temperature sensor may be configured as a thermistor.

In addition, the ice making drip tray 33 in which the immersion pipe 32 of the ice making evaporator 31 is immersed for ice formation may have various configurations. For example, the ice tray 33 has a first drip tray 34 for receiving raw water for ice making such that ice is generated through the ice tray 30 and the raw water for ice making by the ice tray 30. After cooling, a second drip tray 35 for receiving raw water for ice remaining in the first drip tray 34 in the process of emptying the first drip tray 34 is provided.

The first drip tray 34 has an accommodation space of a predetermined size to accommodate the raw water for ice making. At this time, the raw water for ice-making supplied to the first drip tray 34 may be supplied from the purified water tank 10.

In addition, the immersion pipe 32 of the ice making evaporator 31 is immersed in the ice making raw water accommodated in the first drip tray 34 to perform ice making.

In addition, the second drip tray 35 is connected to one side of the first drip tray 34 to cool the raw water for ice making and then remains in the first drip tray 34 in the defrosting process of emptying the first drip tray 34. The ice making water is configured to move and receive.

At this time, the rotation of the ice-making drip tray 33 is rotated about the drip tray rotation shaft 39 from the ice-making position to the ice-free position by a drip tray rotating means (not shown) such as a rotary motor.

After the defrosting operation is completed, the remaining raw water moved to the second drip tray 35 is transferred to the first drip tray 34 as the deicing drip tray 33 returns from the de-icing position to the de-icing position by the drip tray rotating means. Go back.

At this time, additional water is supplied from the cold water tank 20 or the purified water tank 10 in order to supply insufficient ice water.

Meanwhile, the ice tray 33 may further include a guide grill 36 mounted on an upper portion of the second tray 35.

The guide grill 36 allows the deicing raw water remaining in the first drip tray 34 to flow into the second drip tray 35 during a defrosting process in which the first drip tray 34 is empty. A water inlet 37 having a smaller size than the ice may be formed to fall toward the ice storage 40 or the cold water tank 20.

In addition, the ice purifier 100 according to the present invention may include an ice storage 40 for storing the ice generated through the ice making unit 30. The ice storage 40 is installed at a lower position than the ice making unit 30 so as to accommodate the ice that has been removed from the ice making unit 30 and dropped.

At this time, the ice reservoir 40 may be provided with an ice discharge means 41, such as a screw for taking out the ice, ice is discharged when the ice discharge means 41 is rotated about the rotating shaft 42 do.

In addition, the ice purifier 100 according to the present invention further includes a guide member 50 for guiding the ice generated in the ice making unit 30 to be selectively supplied to the ice storage 40 or the cold water tank 20. It may include.

The guide member 50 is provided between a first position for guiding the ice generated in the ice making unit 30 to be supplied to the ice storage 40 and a second position for guiding the cold water tank 20 to be supplied. It can rotate about the rotating shaft 51 through the rotation driving means (not shown).

Since the ice is selectively supplied to the ice reservoir 40 and the cold water tank 20 through the rotation of the guide member 50, the supply structure of the ice is simple, and the ice reservoir 40 and the cold water tank 20 are provided. It is possible to supply ice stably.

Desorption detection method for the ice tray for ice water purifier according to the present invention configured as described above are as follows.

3 is a control flowchart illustrating a desorption detection method of an ice tray according to the present invention, and FIG. 4 is a graph showing the temperature of an ice maker evaporator against an internal temperature of an ice purifier according to desorption of an ice tray.

Referring to FIG. 3, in the method for detecting desorption of the drip tray for ice water purifier according to the present invention, first, a predetermined time elapses after a predetermined time elapses from the de-icing system on in order to perform an ice making process. Is detected by the temperature sensor 38 installed in the ice making evaporator 31 (S10).

In general, the time required for the ice making process is 12 to 13 minutes, and a predetermined time from turning on the ice making system for measuring a temperature of the ice making evaporator 31 in a stabilized state after starting the ice making system, for example, 5 At the time elapsed, the temperature T ₁ of the ice making evaporator 31 is measured. In this case, the temperature T ₁ of the ice making evaporator 31 may sense the temperature of the refrigerant by the temperature sensor 38 at the outlet side of the ice making evaporator 31.

Then, in order to determine whether or not the ice-cold drip tray 33 is attached or detached, the temperature T ₁ of the ice-making evaporator detected by the temperature sensor 31 is compared with a predetermined reference temperature T _r (S20). .

At this time, the reference temperature (T _r ) of the deicing evaporator 31 after a predetermined time elapses from the de-icing system on in accordance with the temperature inside the ice purifier 100 in the unmounted drip tray 33 The temperature of the refrigerant is measured and stored in advance at the outlet side, or the factors of the external environment for stability at the temperature at the outlet side of the ice making evaporator 31 measured when the ice tray 33 is not installed. The temperature obtained by adding a predetermined value in consideration of the temperature inside the ice water purifier, the cooling efficiency, and the like can be stored as the reference temperature T _r . In measuring the reference temperature (T _r ), a time point after a predetermined time elapses from turning on the ice making system is a time point when 5 minutes have elapsed, as in the case of detecting the temperature of the ice making evaporator 31.

In addition, when the detected temperature T ₁ of the ice making evaporator 31 is less than or equal to the reference temperature T _r , it is determined that the ice making tray 33 is not mounted (S30).

4 shows the temperature of the ice making evaporator 31 with the ice tray 33 mounted on the internal temperature of the ice water purifier 100 at a time point 5 minutes after the ice making system is turned on, and the ice tray 33 for ice making. The temperature of the ice making evaporator 31 is shown in the non-mounted state. For example, when the internal temperature of the ice water purifier 100 is 18 ° C., the temperature of the ice making evaporator 31 in the mounted state of the ice tray 33 is about minus 18 ° C., and the state of the ice tray 33 is not mounted. Equivalent to about minus 28 ℃. However, the temperature of the ice-making evaporator 31 according to the desorption of the ice-making drip tray 33 may vary slightly depending on the type of product or the environment of use.

Therefore, it is possible to detect whether the ice tray 33 is detached due to the difference in temperature depending on whether the ice tray 33 is detached. At this time, the reference temperature (T _r ) is based on the temperature plus a predetermined value in order to determine whether the deicing evaporator (31) is detached stably due to factors of the external environment.

Therefore, when the temperature T ₁ of the refrigerant sensed at the outlet side of the ice making evaporator 31 in the on state of the ice making system is less than or equal to the reference temperature T _r , it is determined that the ice making tray 33 is not mounted.

In addition, when it is determined that the ice tray 33 is not mounted, the ice tray 33 may be displayed as unmounted, and the ice making system may be stopped (S40).

In this way, the ice maker drip tray 33 of the ice water purifier 100 displays the unmounted state so that the user recognizes it, and stops the ice making system to operate the ice maker system in operation without the ice tray 33 installed. The breakage of the evaporator can be prevented.

On the other hand, when the detected temperature T ₁ of the ice making evaporator 33 exceeds the reference temperature T _r , the ice making tray 33 is mounted, and thus the ice making process is continued. When the ice making process is completed, the ice generated by rotating the ice receiving tray 33 may be defrosted (S50).

The iced ice is stored in the cold water tank 20 or the ice storage 40 by the guide member 50.

1 is a simplified view showing the internal structure of the ice water purifier according to the present invention.

Figure 2 is a perspective view showing an ice making unit provided in the ice purifier according to the present invention.

3 is a control flow diagram illustrating a method for detecting detachment of a drip tray for ice making according to the present invention.

4 is a graph showing the temperature of the ice making evaporator to the internal temperature of the ice water purifier according to the desorption of the ice tray.

<Explanation of symbols on main parts of the drawings>

10: water purification tank 20: cold water tank

30: ice making unit 31: ice making evaporator

32: dip tube 33: ice tray

34: first drip tray 35: second drip tray

36: guide grill 37: water inlet

40: ice storage 41: ice discharge means

50: guide member

Claims (5)

In the ice water purifier desorption detection method for ice water purifier to cool the water contained in the ice tray drip tray configured to be rotatable, Sensing a temperature of the ice making evaporator after a predetermined time elapses from the ice making system on; Comparing the sensed temperature with a preset reference temperature; Determining that the ice tray is not mounted when the sensed temperature is lower than the reference temperature; And Stopping the ice making system when it is determined that the drip tray is not mounted; Desorption detection method for the ice tray for ice water purifier comprising a. The method according to claim 1, Detecting the temperature of the ice-making evaporator is a desorption detection method of the ice tray for ice water purifier, characterized in that for detecting the temperature of the refrigerant at the outlet side of the ice-making evaporator. The method according to claim 1, The reference temperature is the ice, characterized in that a predetermined value is added to the temperature of the refrigerant at the outlet side of the ice making evaporator after a predetermined time elapses from the ice making system on (on) in accordance with the temperature inside the ice water purifier without the ice trays Desorption detection method of water tray for ice maker. The method according to claim 1, And determining that the ice tray is not mounted when the ice tray is determined to be unmounted. The method according to claim 1, Defrosting and demounting detection method for ice water purifiers for ice water purifier further comprising the step of performing the ice making process when the detected temperature exceeds the reference temperature, by rotating the ice tray drip.

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