KR20080103860A - Ice maker - Google Patents

Abstract

An icing device is provided to be able to measure more accurately the deiceing complete time by detecting the amount of the water remaining in the ice tray or the size of the ice so that the ice manufacturing finish whether or not is judged. An icing device includes the ice tray in which the water of the predetermined amount is continuously provided and the ice is made(10), the ice conveying unit separating the water of the ice tray from the ice made in the ice tray by being installed transfer available about the water of the ice tray, the ice manufacturing finish decision unit detecting amount of the water remaining in the ice tray and determining the ice manufacturing finish when the ice is separated in the ice tray, and the control unit controlling the transfer motion of the ice conveying unit according to the determination of the ice manufacturing finish decision unit. The ice conveying unit is made of the icing part(21) and lifting unit(22).

Description

Ice maker {ICE MAKER}

1 is a perspective view showing an embodiment of the ice making apparatus of the present invention,

2 and 3 are schematic views showing a state change when the ice making process and the ice making is completed in the ice making apparatus according to FIG.

4 and 5 are schematic views showing other embodiments of the apparatus for determining whether the ice making is completed in the ice making apparatus according to FIG.

6 is a perspective view showing another embodiment of the ice making apparatus of the present invention;

7 and 8 are schematic views showing a state change when the ice making process and the ice making is completed in the ice making apparatus according to FIG.

9 and 10 are schematic views showing another embodiment of an apparatus for breaking ice making completion in the ice making apparatus according to Figure 6;

** Explanation of symbols for main parts of drawings **

10: ice tray 20: ice transfer unit

21: freezing unit 22: lifting unit

30: ice making completion detection unit 31: buoy

32: buoy detection unit 33: deicing completion unit

35 transmitter 36 receiver

37: deicing completed portion 131: first electrode

32: second electrode 231: quantity detection unit

335 detection line 435 detection line

436: vibration generator 437: vibration detector

The present invention relates to an ice making apparatus of a refrigerator.

In recent years, large refrigerators have built-in ice makers that can produce some form of ice. The ice making device is configured to supply a predetermined amount of water to the ice making container and then to supply ice to ice the ice, and then to transfer the ice of the ice making container to the ice storage container using the ice making device to store the ice.

Determination of the completion of the de-icing in the above-mentioned ice-making device was to detect the temperature of the ice-making vessel using a temperature sensor and to determine whether the ice-making is completed according to the detected value of the temperature of the ice-making vessel.

However, as described above, in the method of determining whether the ice making is completed by changing the temperature of the ice making container, a detection error of the temperature sensor may occur because the temperature change of the ice making container before and after the actual ice making is not so large. There was a possibility that the ice quality could be degraded because the icebreaking operation did not proceed. In particular, since the ice is less cooled in the transparent ice manufacturing process than in the opaque ice manufacturing process, the temperature change is more insignificant, and it is not accurate to judge whether the ice making is completed by changing the temperature of the ice making container. Could.

The present invention solves the problems of the conventional ice making device as described above, and detects the amount of water remaining in the ice making container or detects the size of the ice to determine whether the ice making is completed so that the ice making completion time can be measured more accurately. It is an object of the present invention to provide an ice making device.

In order to achieve the object of the present invention, an ice-making container that is continuously supplied with a certain amount of water to make ice; An ice conveying unit installed to be transportable with respect to the water of the ice making container and separating the ice made in the ice making container from the water of the ice making container; An ice making completion determination unit that detects the amount of water remaining in the ice making container and determines the completion of ice making when the ice is separated from the ice making container; And a control unit for controlling a transfer operation of the ice transfer unit in accordance with the determination of the ice making completion determination unit.

In addition, an ice-making container in which a predetermined amount of water is continuously supplied to make ice; An ice conveying unit installed to be transported up and down with respect to the water of the ice making container and separating the ice made in the ice making container from the water of the ice making container; An ice making completion unit determining the ice making completion by detecting the size of the ice separated from the ice making container; And a control unit for controlling a transfer operation of the ice transfer unit in accordance with the determination of the ice making completion determination unit.

Hereinafter, the ice making apparatus according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

1 is a perspective view showing an embodiment of the ice making apparatus of the present invention, Figures 2 and 3 is a schematic view showing a state change when the ice making process and the completion of ice in the ice making apparatus according to Figure 1, Figures 4 and 5 Figure 2 is a schematic diagram showing other embodiments of the apparatus for determining whether the ice making is completed in the ice making apparatus according to.

As shown therein, the ice making apparatus according to the present invention includes an ice making unit 10 in which ice is made and an ice conveying unit 20 that separates the ice made in the ice making container 10 from the water of the ice making container 10. And an ice making completion determination unit 30 which detects the amount of water remaining in the ice making container 10 when ice is separated from the ice making container 10 and installed in the ice making container 10. A control unit (not shown) for controlling the lifting operation of the ice transfer unit 20 according to the determination of the ice making completion determination unit 30 is included.

The ice making container 10 is connected to a water supply device so that a predetermined amount of water can be continuously supplied, and the inside thereof may be formed to form a single space as shown in FIG. 1, and each ice may be iced. It may be divided into a plurality of so that. In addition, the ice making container 10 may be provided with a cooling device or a heater on the bottom or periphery thereof. In particular, when the heater is installed on the bottom or periphery of the ice maker 10, a temperature difference is generated inside the ice maker 10 during freezing, so that bubbles generated during freezing can be discharged, which is more effective in manufacturing transparent ice. Can be.

The ice transfer unit 20 is a part of the ice immersed in the water of the ice container 10, the ice part 21 to the ice (I) on the surface, and the ice lifting unit 21 by lifting up and down the ice 21 A lifting portion 22 to allow (I) to be separated from the water or submerged again.

The freezing unit 21 is a cold refrigerant is supplied directly by a separate refrigeration cycle apparatus to maintain the surface temperature below the freezing point or a fan for supplying cold air on one side or a plurality of heat exchange area to expand The heat dissipation fins may be installed to be in contact with each other. In addition, the freezing unit 21 may be further provided with a separate thawing unit so as to transfer and separate the frozen ice upon completion of freezing. For example, the refrigeration cycle apparatus may be controlled so that a hot refrigerant may be supplied to the inside of the freezing unit 21, or a separate heater (not shown) may be installed inside the freezing unit 21.

The ice making completion determination unit 30 is a float 31 installed to float in the water of the ice making container 10 and the ice making container 10 is installed to detect a change in position of the buoy 31. It consists of a buoy detection unit 32 and an ice making completion unit 33 for determining the degree of ice making according to the value detected by the buoy detection unit 32.

The buoy 31 may be formed of a material and size that can react sensitively to the change of water filled in the ice making container. And the buoy detection unit 32 is a buoy according to the change of the magnetic force transmitted from the buoy 31 by installing a magnetic sensor to detect the magnetic force on the buoy 31, the magnet embedded in the buoy (31) It can be configured to detect the height change of 31 and calculate the change in the water level to determine the degree of ice freezing. In this way, if the determined degree of freezing is suitable, the ice is transported to the ice storage container (not shown) using the ice transfer unit 20, but if the degree of freezing is insufficient, the ice transfer unit 20 freezes ( The ice-making completion judging unit 30 directly controls or transfers a signal to another control unit so that the 21 is put back into the water to continue the freezing operation. Here, a kind of tack switch type sensor may be used above the buoy 31 and the buoy 31 corresponding thereto.

Meanwhile, the ice making completion determination unit 30 may directly detect the water level of the ice making container 10 to determine the degree of ice making. For example, as shown in FIG. 4, the first electrode 131 is installed on the bottom side of the ice making container 10, and the second electrode 132 is installed on the upper side, precisely, the height of ice making completion. Since the electrode 132 is higher than the electrode 132, current flows between the first electrode 131 and the second electrode 132, but the ice is frozen in the freezing portion 21 when the freezing portion 21 is raised after the completion of ice making. The water level is lowered by the mass of, so that the water level of the ice making container 10 is lower than the second electrode 132. In this case, a current does not pass between the first electrode 131 and the second electrode 132, and thus, it may be determined that icing is completed. Although not shown in the drawings, a water level sensor using a signal reflected from the water surface may be installed by having a separate transmitter and a receiver above the water surface.

In addition, the ice making completion determination unit 30 may directly detect the quantity of the ice making container 10 to determine the degree of ice making. For example, as illustrated in FIG. 5, the ice making completion determination unit 30 is installed at the bottom of the ice making container 10 and detects a change in quantity by the quantity detecting unit 231 and the quantity detecting unit 231. It consists of an ice making completion unit (not shown) for determining the degree of ice making according to the detected value. Here, the quantity detecting unit 231 may be made of a mass sensor that detects the mass change of the ice making container 10 including water and determines the degree of freezing according to the change of the value.

In the figure, h1, which is not described, indicates the level of the freezing process and h2 is the level after freezing.

The ice making apparatus according to the present invention as described above has the following effects.

That is, as shown in FIG. 2, the ice container 10 is filled with a predetermined amount of water, and the ice part 21 of the ice transfer unit 20 is submerged in the water of the ice container 10. When cold air is directly supplied to 21 or cold air is supplied to the entire ice-making container 10, ice begins to freeze on the freezing part 21.

Thereafter, after a predetermined time passes, the freezing unit 21 is separated from the water of the ice making container 10 by the ice transfer unit 20. At this time, the water level of the ice making container 10 is lowered, which means that the buoy detecting unit 32 detects the height change of the buoy 31 floating on the water of the ice making container 10 to determine the ice making completion unit ( 33).

Subsequently, the ice making completion determination unit 33 receiving the signal from the buoy detection unit 32 recognizes the signal as the current water level and compares it with the stored reference water level, and the water is lowered below the reference water level by the comparison result. If it is determined that the ice is frozen in the freezing unit 21 is determined to be properly frozen, the ice transfer unit 20 transfers the ice to the ice storage container while the comparison result is still determined to be above the standard water level When the ice transfer unit 20 by the icing unit 921 is lowered again to repeat a series of processes to be submerged in the water of the ice making container (10).

On the other hand, the ice-making completion determination unit 30 is provided with a buoy as shown in Figures 1 to 3 even if the water level sensor or a mass sensor is applied as shown in Figures 4 and 5 of the buoy The degree of freezing according to the height change is judged to be similar to a series of processes to complete or continue the ice making operation. Detailed description thereof will be omitted.

Another embodiment of the ice making apparatus according to the present invention is as follows.

That is, in the above-described embodiment, the degree of freezing was determined according to the change in the quantity of water filled in the ice making container 10. However, the present embodiment detects the size of the frozen ice and determines the degree of freezing according to the size of the ice. It is.

For example, as shown in FIG. 6, the ice making apparatus of the present embodiment is provided with an ice container 10 in which a predetermined amount of water is continuously supplied to make ice, and is transportable with respect to the water of the ice container 10. Ice transfer unit 20 for separating the ice made in the (10) and the water of the ice making container 10, and the ice making completion determination unit for detecting the completion of the ice by detecting the size of the ice separated from the ice making container (10) 30, and a control unit (not shown) for controlling the transfer operation of the ice transfer unit 20 in accordance with the determination of the ice making completion determination unit (30).

Here, since the configuration or operation of the ice maker 100, the ice transfer unit 20 and the control unit 40 are similar to those of the above-described embodiment, a detailed description thereof will be omitted.

However, the ice making completion determination unit 30 of the present embodiment is installed in the periphery of the ice making container 10 and transmits a signal, and is provided on the opposite side of the transmitter 35 so as to transmit the signal. It consists of a sensor with a receiver 36 for judging whether the ice is frozen to an appropriate size depending on whether or not a signal transmitted from is received. As such a sensor, an electromagnetic wave sensor such as an infrared sensor or a visible light sensor may be used.

When the above-described electromagnetic wave sensor is provided, the ice-making unit 21 is separated from the ice-making container by the elevating unit 22 of the ice transfer unit 20 after a predetermined time elapses, and at the same time the electromagnetic wave sensor Electromagnetic wave is transmitted from the transmitter of the receiver and the signal is received by the receiver 36 on the opposite side. As shown in FIG. 7, when the signal is received by the receiver 36, the ice making determination unit 37 of the ice making determination unit 30 determines that the size of the ice has not been properly frozen. 22) causes the icing unit 21 to be immersed again in the ice making container. On the other hand, as shown in FIG. 8, when the signal is covered by the ice I and receives the signal transmitted from the transmitting unit 35 from the receiving unit 36, The control unit 33 of the ice making determination unit 30 determines that ice (I) is frozen to an appropriate size and a series of processes in which the ice is transferred to an ice storage container (not shown) by the ice transfer unit 20. Will be repeated. Here, the transmitter 35 and the receiver 36 may be arranged side by side on the ice making container 10 so that electromagnetic waves transmitted from the transmitter 35 may be reflected by ice and received by the receiver 36. .

On the other hand, as a sensor for measuring the size of the ice, in addition to the above-described electromagnetic wave sensor, the sensor may be installed at any position and a contact sensor for determining the degree of freezing of the ice depending on whether the ice contacts the signal of the sensor. . For example, as shown in FIG. 9, a kind of sensing line 335 such as an iron wire is installed at a predetermined height of the ice making container 10, and a temperature change of the sensing line 335 is detected or the sensing line 335 is provided. When the ice is in contact with the ice detected by using the electric current between the sensing line 335 and the freezing unit 21 by the moisture buried in the ice, or as shown in Figure 10, the vibration of one side of the sensing line 435 When the generator 436 is installed and the vibration sensor 437 is installed at the opposite side to vibrate the sensing line 435 in the vibration generator 436, the amplitude and the amplitude that change when ice is in contact with the sensing line 435. The vibration frequency is received by the vibration sensor 437 to determine the freezing state of the ice.

In this way, it is possible to detect the ice making state of the ice more accurately as it is determined whether the ice iced in the ice making container is properly iced by using the quantity change of the ice making container or the size of the ice. In particular, even during the manufacture of transparent ice without a large temperature change before and after ice making can accurately determine the ice making state can improve the quality of the ice.

The ice making apparatus according to the present invention uses a buoy in the ice making container or detects a quantity change when the ice is separated by using a water level sensor or a mass sensor, and determines an ice making state based on the quantity detection, or electromagnetic waves. By detecting the size of the ice using a sensor or a contact sensor and determining the ice making state accordingly, the ice making state of the ice making container can be judged more accurately, and the transparent ice is transparent even if the temperature difference before and after ice making is not large. The ice can be made quickly, increasing the reliability of the ice maker.

Claims (14)

An ice making container in which ice is made by continuously supplying a certain amount of water; An ice conveying unit installed to be transportable with respect to the water of the ice making container and separating the ice made in the ice making container from the water of the ice making container; An ice making completion determination unit that detects the amount of water remaining in the ice making container and determines the completion of ice making when the ice is separated from the ice making container; And And a control unit for controlling a transfer operation of the ice transfer unit according to the determination of the ice making completion determination unit. The method of claim 1, The ice transfer unit is an ice making unit comprising a freezing portion, a part of which is immersed in the water of the ice making vessel to freeze the ice on the surface, and the lifting portion for lifting the ice up and down so that the ice is separated from the water or submerged again. The method of claim 2, The ice transfer unit is an ice making apparatus further comprises a thawing unit for supplying heat above the freezing point of water to the ice to separate the ice from the ice. The method of claim 1, The ice making completion unit is a buoy installed to float in the water of the ice making container, a buoy detecting portion installed in the ice making container to detect a position change of the buoy, and ice according to the value detected by the buoy detecting portion. An ice making device comprising an ice making completion part determining the ice making degree of the ice. The method of claim 1, The ice making determination unit comprises a water level detecting unit for detecting a change in the water level of the ice making container, and an ice making completion unit for determining the degree of ice making according to the value detected by the water level detecting unit. The method of claim 5, The ice level detecting unit is provided with different electrodes on each of the upper and lower sides of the ice making container, and the ice making completion unit determines the degree of ice making according to whether the different electrodes are energized by the change of the water level. The method of claim 1, The ice making completion unit includes an ice making unit that detects a change in quantity of the ice making container, and an ice making completion unit that determines the degree of ice making according to the value detected by the quantity detecting unit. An ice making container in which ice is made by continuously supplying a certain amount of water; An ice conveying unit installed to be transportable with respect to the water of the ice making container and separating the ice made in the ice making container from the water of the ice making container; An ice making completion unit determining the ice making completion by detecting the size of the ice separated from the ice making container; And And a control unit for controlling a transfer operation of the ice transfer unit according to the determination of the ice making completion determination unit. The method of claim 8, The ice transfer unit is an ice making unit comprising a freezing portion, a part of which is immersed in the water of the ice making vessel to freeze the ice on the surface, and the lifting portion for lifting the ice up and down so that the ice is separated from the water or submerged again. The method of claim 8, The ice transfer unit is an ice making apparatus further comprises a thawing unit for supplying heat above the freezing point of water to the ice to separate the ice from the ice. The method of claim 8, And the ice-making completion judging unit comprises an electromagnetic wave sensor which transmits electromagnetic waves and determines the degree of freezing of ice according to whether the transmitted signal is received. The method of claim 8, The ice-making completion unit consists of a contact sensor for installing a sensing line around the ice-making container, and determining the degree of freezing of ice according to whether or not the temperature of the sensing line changes when the ice contacts the sensing line. Ice making device. The method of claim 8, The ice-making completion judging unit installs a sensing line around the ice-making container, and when the ice is in contact with the sensing line, a touch sensor for determining the degree of ice freezing according to whether the current is energized by the sensing line. Ice making device consisting of. The method of claim 8, The ice-making completion judging unit installs a sensing line around the ice-making container, and when the ice touches the sensing line, a touch sensor for determining the degree of ice freezing according to whether the amplitude or frequency of the sensing line changes. Ice making device consisting of.

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