KR102637434B1 - Ice maker and Refrigerator having the same - Google Patents

Abstract

The present invention includes an upper tray having a plurality of cells having a hemispherical shape; And a lower tray having a plurality of cells having a hemispherical shape and a communication hole connecting adjacent cells, wherein the upper tray and the lower tray are arranged to be rotatable with each other, and the upper tray When the tray and the lower tray are combined and a plurality of cells are arranged to form a spherical shape, the communication hole connects each cell.

Description

Ice maker and refrigerator including the same {Ice maker and Refrigerator having the same}

The present invention relates to an ice maker and a refrigerator including the same, and more specifically, to an ice maker capable of providing spherical transparent ice and a refrigerator including the same.

When supercooling occurs when freezing water, a rapid phase change occurs and opaque ice is formed. Supercooling refers to a state in which no phase change occurs and no latent heat is released at a temperature below the freezing point. When ice is frozen in a freezer, opaque ice is easily observed. This is the result of supercooled water freezing cloudy due to a rapid phase change. To control the transparency of ice, it is important to control supercooling. To make transparent ice, a method to stop or prevent supercooling is needed.

It is difficult to find technology that takes into account supercooling of water in relation to ice making in general refrigerators. This is thought to be because the development of ice-making technology has focused on ice-making speed rather than ice quality.

The most widely used method to reduce supercooling is the addition of a nucleation agent. Nucleating agents can lower the degree of supercooling of materials through effects such as lowering the nucleation barrier and reducing crystallization time.

However, this supercooling-related technology is difficult to apply to the production of ice for drinking. The use of nucleating agents has several limitations in the production of edible ice and may sometimes be inappropriate. As an extension of water consumption, ice containing additives rather than clean and pure ice may cause resistance to consumers.

In addition, it is expected to be very difficult to find an additive that has a clear supercooling prevention effect and is harmless to the human body, and it is inconvenient to store the nucleating agent in the refrigerator and inject it when making ice.

The present invention is intended to solve the above problems, and the present invention provides an ice maker that can quickly escape from a supercooling phenomenon even if supercooling does not occur or even if a supercooling phenomenon occurs, and a refrigerator including the same.

In one embodiment of the present invention, in order to cancel supercooling of water, the supercooling state is determined using the temperature of the tray, and if it is determined that it is overcooled, the lower tray is rotated by a certain angle to cancel the supercooling state. At this time, it is desirable to select the rotation angle of the lower tray so that water does not overflow. Rotation of the tray can be performed repeatedly while subcooling is terminated. At the point when the temperature of the tray suddenly rises, it is determined that supercooling has ended, and the tray can stop rotating and return to the initial ice-making position.

In another embodiment of the present invention, by adding small grooves to the inter-cell partitions through which crystal nuclei that freeze when supercooling is released can be transferred, supercooling occurring in one cell can be propagated to other cells.

In another embodiment of the present invention, water is supplied to the tray after the tray is cooled, so that water in contact with the tray is not supercooled and ice can be created. That is, crystal nuclei are activated through contact between the surface of the cooled tray and water, and ice can be formed along the contact surface.

In another embodiment of the present invention, in order to produce transparent ice, the water supply is divided to form ice cubes from the first water supply, and ice is made while the remaining water is supplied again. Since the crystal nuclei are activated using ice in water supplied in a small amount initially, supercooling may not occur. Because the amount of water initially supplied is small, ice can be created faster than when water is supplied all at once. Therefore, a situation in which supercooling occurs is quickly terminated, or supercooling is prevented from occurring.

Another embodiment of the present invention provides a method of terminating supercooling by stimulating supercooled water with sparks discharged at high voltage, creating freezing nuclei and creating an energy imbalance. Supercooling is a phenomenon in which water remains water without freezing even when cooled to a stable state and lowered to a temperature below the freezing point. However, when a spark is applied, it can break out of the supercooled state and convert into ice.

The present invention provides the following steps: supplying water and cold air to an ice maker that freezes water, measuring the temperature of the tray using a tray temperature sensor, and measuring the point at which it corresponds to 0 degrees Celsius; measuring the time for the temperature additionally measured by the tray temperature sensor to reach a specific temperature; If the reached time is shorter than a specific time, determining that supercooling has occurred and generating a spark in a tray storing water, a method of controlling an ice maker is provided.

It is also possible to further include measuring the tray temperature again after generating the spark.

If the re-measured temperature is equal to or falls below the previously measured temperature, it is possible to re-ignite the spark.

The electrodes that generate sparks in the water can be arranged to be spaced apart above the surface of the water.

The tray includes an upper tray and a lower tray, and the electrode may be arranged to penetrate the opening of the upper tray.

Also a tray where water is stored; a tray temperature sensor that measures the temperature of the tray; Electrodes arranged to be spaced apart from the water; and a control unit that generates a high-voltage spark at the electrode when it is determined that the water contained in the tray is in a supercooled state according to the temperature measured by the tray temperature sensor.

The electrodes can penetrate the opening of the tray and be arranged so that the surfaces of the water are spaced apart.

It is possible for the electrode to be placed in the center of the opening of the tray.

The present invention provides the following steps: supplying water and cold air to an ice maker that freezes water, measuring the temperature of the tray using a tray temperature sensor, and measuring the point at which it corresponds to 0 degrees Celsius; measuring the time for the temperature additionally measured by the tray temperature sensor to reach a specific temperature; If the reached time is shorter than a specific time, determining that supercooling has occurred and rotating the tray in which water is stored is provided.

It is possible to further include measuring the tray temperature again after rotating the tray.

If the measured temperature again rises above the previously measured temperature, it is possible to stop the rotation of the tray.

If the re-measured temperature is equal to or falls below the previously measured temperature, it is possible to rotate the tray again.

The tray includes an upper tray and a lower tray, the upper tray is fixed, and only the lower tray can be rotated.

At this time, the specific temperature may be below 0 degrees.

The present invention includes the steps of blocking the flow path at the water supply valve that opens and closes the flow path that supplies water to the ice maker; Cooling the ice maker by supplying cold air to the ice maker while no water is supplied to the ice maker; Opening a flow path in the water supply valve to supply water to the ice maker; A control method of an ice maker is provided, including supplying cold air to the ice maker to create ice.

The ice maker includes an upper tray and a lower tray on which ice is produced, and when the ice maker is cooled, either one of the upper tray and the lower tray may be cooled.

In the cooling step, it is possible to cool either the upper tray or the lower tray to 0 degrees or lower.

The temperature of the water supplied to the ice maker may be higher than the temperatures of the upper tray and the lower tray.

In the water supply step, it is possible to supply a set amount without stopping the water supply.

In the ice generation step, it is possible to generate ice by supplying cold air without additionally supplying water.

The present invention includes a first water supply step of supplying water to a tray; cooling water to create ice; A second water supply step of supplying water to the tray where ice was created; A control method of an ice maker including a step of generating ice from a mixture of water and ice is provided.

It is possible to further include the step of checking whether ice has been created before the second water supply step.

It is possible to determine that ice has been created when the temperature measured by the tray temperature sensor is below a certain temperature.

It is possible to determine that ice has been created when a predetermined time has elapsed after the first water supply step is completed.

It is possible to continuously supply cold air to the tray during the first water supply step and the second water supply step.

In the first water supply step, it is possible to supply a smaller amount of water than in the second water supply step.

The present invention includes an upper tray having a plurality of cells having a hemispherical shape; And a lower tray having a plurality of cells having a hemispherical shape and a communication hole connecting adjacent cells, wherein the upper tray and the lower tray are arranged to be rotatable with each other, and the upper tray When the tray and the lower tray are combined and a plurality of cells are arranged to form a spherical shape, the communication hole connects each cell.

The communication hole may be disposed on the upper surface of the lower tray.

The communication hole may have a semicircular cross section.

The communication hole may be arranged on an extension line connecting the centers of each hemispherical cell.

The communication hole can be placed in the upper tray.
While ice making is being performed at the ice making location, the communication hole limits the movement of water between cells and ensures that when supercooling of one cell is terminated, the effect of supercooling is transmitted to other adjacent cells.
A refrigerator according to another aspect includes a first tray having a plurality of first cells forming a portion of a space in which ice is frozen; a tray case disposed on one side of the first tray; a tray cover disposed on the other side of the first tray; and a second tray having a plurality of second cells forming another part of the space, wherein the tray case, the first tray, and the tray cover are combined to form one module, and the tray case includes a heater. It may include a heater case in which a is installed, and an opening including a portion corresponding to the shape of the first cell of the first tray may be formed in the tray cover.
At least one of the first tray and the second tray may include a communication hole that allows the cells to communicate with each other.
The heater case may be provided with an opening including a portion corresponding to the shape of the first cell of the first tray.
It may further include a pusher for separating ice from the first tray, and the pusher may penetrate an opening of the heater case.
The refrigerator includes a second tray case disposed on one side of the second tray; a second tray cover disposed on the other side of the second tray; And it may further include a pusher to separate ice from the second tray.
The pusher may press the second tray and penetrate the second tray case.

According to one embodiment of the present invention, when supercooling occurs, supercooling can be canceled by rotating the tray. Supercooling can be canceled by simply adding logic to rotate the tray without the need for a separate device to cancel supercooling.

As a result of the experiment, supercooling that occurs around -3℃ does not have a significant effect on transparency, so it is possible to determine whether supercooling has occurred up to -3℃ and if supercooling continues to occur after that, supercooling can be canceled by rotating the tray.

Furthermore, supercooling can be canceled by continuously measuring the temperature of the tray and repeatedly performing the process until supercooling is confirmed.

According to another embodiment of the present invention, each cell can be connected to each other to transmit the effect of terminating supercooling in one cell to another cell. By creating small grooves between the partition walls between cells, if supercooling is released in one cell, it can be transferred to other cells and eventually supercooling can be released in all cells. In the end, you can disable supercooling of all cells by disabling only one cell without the need to disable supercooling of all cells in the tray.

According to another embodiment of the present invention, parts other than the tray do not come into contact with water or ice during ice making, and foreign substances such as nucleating agents are not added, making it an appropriate and safe method for eating and drinking. There is no structure that is consumed or worn out, so the effectiveness does not deteriorate even after repeated operation. It is also a safe method to apply inside a refrigerator. It has the advantage of not causing any inconvenience to nearby users as it does not generate noise or vibration during operation.

Additionally, according to another embodiment of the present invention, supercooling can be canceled at the beginning when supercooling occurs, thereby providing transparent ice. In particular, it is possible to prevent opacity when supercooling is terminated without more than 3 degrees difference from the freezing temperature.

1 is a diagram showing a refrigerator according to an embodiment of the present invention.
Figure 2 is a side cross-sectional view illustrating a refrigerator equipped with an ice maker.
Figure 3 is a perspective view showing an ice maker according to an embodiment of the present invention.
Figure 4 is a front view showing an ice maker.
Figure 5 is an exploded perspective view of the ice maker.
Figures 6 to 11 are diagrams showing some components of an ice maker combined.
Figures 12 and 13 are diagrams explaining the process of supplying water to the ice maker.
Figure 14 is a diagram explaining the process of moving ice from an ice maker.
15 is a control block diagram according to one embodiment.
Figure 16 is a diagram illustrating a process for canceling supercooling according to an embodiment.
Figure 17 is a view showing a lower tray and related parts according to another embodiment.
Figure 18 is a plan view of Figure 17.
19 is a diagram illustrating an ice-making method according to another embodiment.
Figure 20 is a diagram explaining an ice-making method according to another embodiment.

Hereinafter, preferred embodiments of the present invention that can specifically realize the above object will be described with reference to the attached drawings.

In this process, the size or shape of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. Additionally, terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. Definitions of these terms should be made based on the content throughout this specification.

FIG. 1 is a diagram illustrating a refrigerator according to an embodiment of the present invention, and FIG. 2 is a side cross-sectional view illustrating a refrigerator equipped with an ice maker.

As shown in FIG. 1(a), the refrigerator according to an embodiment of the present invention includes a plurality of doors 10, 20, and 30 that open and close the storage compartment. The doors 10, 20, and 30 include doors 10 and 20 that open and close the storage compartment by rotating and a door 30 that opens and closes the storage compartment by sliding.

Figure 1(b) is a cross-sectional view seen from the rear of the refrigerator, where the refrigerator cabinet 14 may include a refrigerating chamber 18 and a freezing chamber 32. The refrigerating compartment 14 is located at the upper side, and the freezing compartment 32 is located at the lower side, so that each storage compartment can be opened and closed individually by each door. Unlike the present embodiment, the present invention can also be applied to a refrigerator in which a freezer compartment is placed at the top and a refrigerator compartment is placed at the bottom.

The freezer compartment 32 can be divided into an upper space and a lower space, and the lower space is provided with a drawer 40 that can be drawn in and out of the space. Although the freezer compartment 32 can be opened and closed by a single door 30, it can be divided into two spaces.

An ice maker 200 capable of producing ice may be provided in the upper space of the freezer compartment 32. An ice bucket 600 may be provided at a lower portion of the ice maker 200 into which ice produced by the ice maker 200 is dropped and stored. The user can take out the ice bucket 600 and use the ice stored in the ice bucket 600. The ice bucket 600 may be mounted on the upper side of the horizontal wall dividing the upper space and lower space of the freezer compartment 32.

Referring to FIG. 2, the cabinet 14 is provided with a tuft 50 that supplies cold air to the ice maker 200. The duct 50 cools the ice maker 200 by discharging cold air supplied from an evaporator where the refrigerant compressed by the compressor is evaporated. Ice may be created inside the ice maker 200 by cold air supplied to the ice maker 200.

In Figure 2, the right side may be the rear of the refrigerator, and the left side may be the front of the refrigerator, that is, the part where the door is installed. At this time, the duct 50 is disposed at the rear of the cabinet 14 and can discharge cold air toward the front of the cabinet 14. The ice maker 200 is disposed in front of the duct 50.

The discharge port of the duct 50 is located on the ceiling of the freezer compartment 32, making it possible to discharge cold air to the upper side of the ice maker 200.

Figure 3 is a perspective view showing an ice maker according to an embodiment of the present invention, Figure 4 is a front view showing the ice maker, and Figure 5 is an exploded perspective view of the ice maker.

FIGS. 3A and 4A are diagrams showing the bracket 220 that secures the ice maker 200 to the freezer compartment 32, and FIGS. 3B and 4B are diagrams showing the bracket 220 removed. Each component of the ice maker 200 is provided inside or outside the bracket 220, so that the ice maker 200 can form one assembly. Accordingly, the ice maker 200 can be installed on the ceiling of the freezer compartment 32.

A peel cup 240 is installed on the upper inner surface of the bracket 200. The peel cup 240 is provided with openings on the upper and lower sides, respectively, and guides the water supplied to the upper side of the peel cup 240 to the lower side of the peel cup 240. The upper opening of the feel cup 240 is larger than the lower opening, which may limit the discharge range of water guided to the lower part through the feel cup 240.

A water supply pipe through which water is supplied is installed on the upper side of the pill cup 240, so that water can be supplied to the pill cup 240 and moved to the lower part. The peel cup 240 prevents water discharged from the water supply pipe from falling from a high position, thereby preventing water from splashing. Since the pill cup 240 is disposed below the water supply pipe, water is guided to the pill cup 240 without splashing, and the amount of water splashing can be reduced even if it moves downward due to the lowered height.

The ice maker 200 includes an upper tray 320 and a lower tray 380. The upper tray 320 and the lower tray 380 may include a plurality of cells in which a plurality of ice can be generated. When the cells provided in the upper tray 320 and the cells provided in the lower tray 380 overlap, they form a spherical shape, and when water is supplied and cooled, spherical ice can be created.

The upper tray 320 is provided with openings on the upper and lower sides so that water falling from the upper side of the upper tray 320 can move downward.

An upper tray cover 340 is provided below the upper tray 320. The upper tray cover 340 has openings formed to correspond to each cell shape of the upper tray 320 and can be coupled to the lower side of the upper tray 320.

The upper tray case 300 is coupled to the upper side of the upper tray 320, so that the upper appearance of the upper tray 320 can be maintained. An upper heater case 280 is provided in the upper tray case 300. The heater case 280 is equipped with a heater to supply heat to the upper part of the ice maker 200. The heater may be embedded in the heater case 280 or installed on one side.

The upper tray case 300 is provided with a guide groove 302 that is inclined on the upper side and extends vertically on the lower side. The guide groove 302 may be provided inside a member extending upwardly of the tray case 300.

The guide protrusion 262 of the upper pusher 260 is inserted into the guide groove 302, so that the guide protrusion 262 can be guided along the guide groove 302. The upper pusher 260 is provided with an extension portion 264 extending equal to the number of cells in the upper tray 320, and can push ice located in each cell.

The guide protrusion 262 of the upper pusher 260 is coupled to the pusher link 500. At this time, the guide protrusion 262 is rotatably coupled to the pusher link 500, so that when the pusher link 500 moves, the upper pusher 260 can also move along the guide groove 302.

A lower tray cover 360 is provided on the upper side of the lower tray 380 to maintain the appearance of the lower tray 380. The lower tray 380 has a shape that protrudes upward to separate a plurality of cells forming a space where individual ice can be created, and the lower tray cover 360 can cover the cells that protrude upward. there is.

A lower tray case 400 is provided at the lower part of the lower tray 380, so that the cell shape protruding from the lower part of the lower tray 380 can be maintained. A spring 402 is provided on one side of the lower tray case 400.

A lower tray heater case 420 is provided below the lower tray case 400. A heater is provided in the lower tray heater case 420 to supply heat to the lower part of the ice maker 200.

The ice maker 200 is equipped with a motor unit 480 that provides rotational force.

A through hole 282 is formed in an extension portion extending downward on one side of the upper tray case 300. A through hole 404 is formed in an extension portion extending to one side of the lower tray case 400. A shaft 440 penetrating both the through hole 282 and the through hole 404 is provided, and rotary arms 460 are provided at both ends of the shaft 440, respectively. The shaft 440 can be rotated by receiving rotational force from the motor unit 480.

One end of the rotary arm 460 is connected to one end of the spring 402, so that when the spring 402 is tensioned, the position of the rotary arm 460 can be moved to the initial value by a restoring force.

In the motor unit 480, a motor and a plurality of gears may be coupled to each other.

The full ice detection lever 520 is connected to the motor unit 480, so that the full ice detection lever 520 can be rotated by the rotational force provided by the motor unit 480.

The full ice detection lever 520 has an overall 'ㄷ' shape and may include a vertically extending portion at both ends and a horizontally disposed portion connecting the two vertically extending portions. Of the two vertically extending parts, one is coupled to the motor unit 480 and the other is coupled to the bracket 220, so that the full ice detection lever 520 is rotated and connected to the ice bucket 600. Stored ice can be detected.

A lower pusher 540 is provided on the inner lower side of the bracket 220. The lower pusher 540 is provided with a coupling piece 542 coupled to the bracket 220 and a plurality of extension parts 544 installed on the coupling piece 542. The plurality of extension parts 544 are provided to equal the number of cells provided in the lower tray 380, so that ice generated in the cells of the lower tray 380 is separated from the lower tray 380. It performs the function of pushing things to become possible.

The upper tray case 300 and the lower tray case 400 are rotatably coupled to each other with respect to the shaft 440 and can be arranged so that the angle changes around the shaft 440.

The upper tray 320 and the lower tray 380 are each made of a material that is easily deformable, such as silicon, and are momentarily deformed when pressed by each pusher, so that the generated ice can be easily separated from the tray. .

Figures 6 to 11 are diagrams showing a state in which some components of an ice maker are combined.

FIG. 6 is a diagram illustrating a state in which the bracket 220, the peel cup 240, and the lower pusher 540 are coupled. The lower pusher 540 is installed on the inner surface of the bracket 220, and the extension of the lower pusher 540 is disposed so that the direction in which it extends from the coupling piece 542 is not vertical but is inclined downward.

FIG. 7 is a diagram showing a state in which the upper heater case 280 and the upper tray case 300 are combined.

The upper heater case 280 may be arranged so that its horizontal surface is spaced downward from the lower side of the upper tray case 300. The upper heater case 280 and the upper tray case 300 have openings corresponding to each cell of the upper tray 320 to allow water to pass through the upper side, and the shape of each opening is different from each other. It is possible to form a shape corresponding to the cell.

FIG. 8 is a diagram showing a state in which the upper tray case 300, the upper tray 320, and the upper tray cover 340 are combined.

The tray cover 340 is disposed between the upper tray 320 and the upper tray case 300.

The upper tray case 300, the upper tray 320, and the tray cover 340 are combined as one module, so that the upper tray case 300, the upper tray 320, and the tray cover 340 ) is disposed on the shaft 440 so that it can rotate together like a single member.

FIG. 9 is a diagram showing a state in which the lower tray 380, the lower tray cover 360, and the lower tray case 400 are combined.

With the lower tray 380 in between, the lower tray cover 360 is disposed on the upper side, and the lower tray case 400 is disposed on the lower side.

Each cell of the lower tray 380 has a hemispherical shape to form the bottom of a spherical ice cube.

FIG. 10 is a diagram showing a state in which the lower tray cover 360, lower tray 380, lower tray case 400, and lower heater case 420 are combined.

The lower heater case 420 is disposed on the lower surface of the lower tray case and can fix a heater that supplies heat to the lower tray 380.

FIG. 11 is a diagram illustrating a state in which FIGS. 8 and 10 are combined and the rotary arm 460, shaft 440, and pusher link 500 are combined.

One end of the rotary arm 460 is coupled to the shaft 440, and the other end is coupled to the spring 402. One end of the pusher link 500 is coupled to the upper pusher 260, and the other end is arranged to rotate with respect to the shaft 440.

Figures 12 and 13 are diagrams explaining the process of supplying water to the ice maker.

FIG. 12 is a diagram explaining the process of supplying water while looking at the ice maker from the side, and FIG. 13 is a diagram explaining the process of supplying water while looking at the ice maker from the front.

As shown in FIG. 12A , the upper tray 320 and the lower tray 380 are placed apart from each other, and then the lower tray 380 is rotated toward the upper tray 320 as shown in FIG. 12B . At this time, although the upper tray 320 and the lower tray 380 partially overlap, the upper tray 320 and the lower tray 380 are not completely engaged, so the inner space does not have a spherical shape.

As shown in Figure 12c, water is supplied into the tray through the fill cup 240. Since the upper tray 320 and the lower tray 380 are not completely engaged, some of the water flows out of the upper tray 320. However, since the lower tray 380 has a portion formed to surround the upper side of the upper tray 320 to be spaced apart, water does not overflow the lower tray 380.

Figure 13 is a diagram specifically explaining Figure 12c, and the state changes in the order of Figures 13a and 13b.

As shown in FIG. 12C, when water is supplied to the upper tray 320 and the lower tray 380 through the fill cup 240, the fill cup 240 is disposed skewed to one side of the tray.

That is, the upper tray 320 is provided with a plurality of cells 322, 324, and 326 for producing a plurality of independent ice. The lower tray 380 is also provided with a plurality of cells 382, 384, and 386 for producing a plurality of independent ice. One spherical ice can be created by combining the cells placed on the upper tray 320 and the cells placed on the lower tray 380.

In FIG. 13, the upper tray 320 and the lower tray 380 are not completely coupled as in 12c, but the front sides are separated so that the water in each cell can move between cells.

As shown in FIG. 13A, when water is supplied to the upper side of the cells 322 and 382 located on the left, the water moves inside the cells 322 and 382. At this time, if the water overflows the cell 382 located on the lower side, the water may move to the cells 384 and 486 located on the left. Since the plurality of cells are not completely isolated from each other, when the water level within the cell rises above a certain level, the water moves to the surrounding cells, filling each cell with water.

When a predetermined amount of water is supplied from a water supply valve disposed in a water supply pipe provided outside the ice maker 200, the flow path may be closed to prevent water from being supplied to the ice maker 200 any more.

Figure 14 is a diagram explaining the process of moving ice from an ice maker.

Referring to FIG. 14, when the lower tray 380 in FIG. 12C is further rotated counterclockwise based on the drawing, the upper tray 320 and the lower tray 380 have a spherical cell as shown in FIG. 14A. It can be arranged to form a shape. The lower tray 380 and the upper tray 320 can be completely combined and arranged so that water is separated into each cell.

When cold air is supplied for a predetermined period of time in the state shown in FIG. 14A, ice is created in the cells of the tray. While water is changed into ice by cold air, the upper tray 320 and the lower tray 380 are engaged with each other, as shown in FIG. 14A, and the water is maintained in a non-moving state.

When ice is created in the cells of the tray, the upper tray 320 is stopped and the lower tray 380 is rotated clockwise, as shown in FIG. 14B.

At this time, because the ice has its own weight, it may fall from the upper tray 320. In this case, as the upper pusher 260 descends on the upper tray 320, ice can be prevented from sticking to the upper tray 320.

Since the lower tray 380 supports the lower portion of the ice, the ice remains mounted on the lower tray 380 even if the lower tray 380 moves clockwise. As shown in FIG. 14B, ice may remain on the lower tray 380 even when the lower tray 380 is rotated beyond the vertical angle.

Therefore, in this embodiment, the lower pusher 540 deforms the bottom of the lower tray 380, and as the lower tray 380 is deformed, the adhesive force between the ice and the lower tray 380 is weakened, so that the ice is transferred to the lower tray 380. It may fall from the tray 380.

The ice may then fall into the ice bucket 600, although not shown in FIG. 14.

Figure 15 is a control block diagram according to one embodiment.

Referring to FIG. 15, an embodiment of the present invention includes a tray temperature sensor 700 that measures the temperature of the upper tray 320 or the lower tray 380.

The temperature measured by the tray temperature sensor 700 is transmitted to the control unit 800.

The control unit 800 can control the motor unit 520 to rotate the motor in the motor unit 520.

The control unit 800 may control the water supply valve 740, which opens and closes the water flow path supplied to the ice maker 200, to supply water to the ice maker 200 or stop the supply.

When the motor unit 520 operates, the lower tray 380 or the full ice detection lever 520 may be rotated.

A first heater 430 is provided in the lower heater case 420. The first heater 430 is disposed in the lower heater case 420 and can supply heat. Since the first heater 430 is disposed at the bottom of the tray, it may refer to a lower heater.

A second heater 290 is provided in the upper heater case 280. The second heater 290 is disposed in the upper heater case 280 and can supply heat. Since the second heater 290 is disposed at the top of the tray, it may refer to an upper heater.

Power is supplied to the first heater 430 and the second heater 290 according to a command from the control unit 800, so that heat can be generated.

Figure 16 is a diagram explaining a process for canceling supercooling according to an embodiment.

Referring to FIG. 16, after water is supplied to the ice maker 200, cold air is supplied to the ice maker 200 through the duct 50.

While ice is being created in the tray, the tray temperature sensor 700 measures the temperature.

If the temperature measured by the tray temperature sensor 700 drops to -3°C within a certain period of time after dropping to 0°C, it can be determined that supercooling occurs. That is, the control unit 700 determines that supercooling occurs when the temperature of the tray drops to -3 degrees at a relatively high speed after dropping to 0 degrees.

At this time, the control unit 800 rotates the lower tray 380. That is, in a state in which the upper tray 320 and the lower tray 380 are engaged with each other as shown in FIG. 16A, the lower tray 380 is rotated clockwise as shown in FIG. 16B, so that the upper tray 320 and the lower tray 380 are aligned with each other. One end of the lower tray 380 can be configured to be spaced apart. Accordingly, supercooling may be terminated as the water contained in the upper tray 320 and the lower tray 380 moves.

Then, the lower tray 380 returns to the position shown in FIG. 16A after rotating to a certain angle.

After the lower tray 380 rotates, if the temperature measured by the tray temperature sensor 700 rises above -3°C, it is determined that supercooling has been terminated and rotation may no longer occur.

Meanwhile, if the temperature measured by the tray temperature sensor continues to drop even after rotating the lower tray 380, it is determined that supercooling has not been terminated and the lower tray 380 can be further rotated.

FIG. 17 is a view showing a lower tray and related parts according to another embodiment, and FIG. 18 is a plan view of FIG. 17.

Referring to FIGS. 17 and 18 , in another embodiment, a communication hole 390 is provided to connect each cell 382, 384, and 386 of the lower tray.

The communication hole 390 connects each cell 382, 384, and 386 with cells 382, 384, and 386 adjacent to the cell. It is not easy for water to freely move between the cells 382, 384, and 386 through the communication hole 390, but because the communication hole 390 exists, each cell 382, 384, and 386 Not completely isolated.

When supercooling is canceled in any one of the cells 382, 384, and 386, the effect of canceling supercooling in other cells among the cells 382, 384, and 386 can be sequentially generated through the communication hole 390. there is.

Since the plurality of cells 382, 384, and 386 can achieve the same effect as a single container through the communication hole 390, the effect of supercooling can be transmitted to other cells.

The communication hole 390 may be smaller than the size of the cells 382, 384, and 386, but may have a semicircular or polygonal cross section. The communication hole 390 can be provided at a location where each cell 382, 384, and 386 is adjacent to each other, so that the length of the communication hole 390 can be made as short as possible.

The communication hole 390 connects each cell 382, 384, and 386 at a straight line distance, so that the volume occupied by the lower tray 380 can be reduced. The communication hole 390 may be arranged on an extension line connecting the centers of each hemispherical cell.

The communication hole 390 may be disposed on the upper surface of the lower tray. Each cell 382, 384, and 386 forms an overall hemispherical shape, and when each cell is combined with a cell of the upper tray, it forms an overall spherical shape. The upper surface of the lower tray 380 may refer to the hemispherical upper surface forming the cells 382, 384, and 386.

Since the communication hole 390 is not a passage for water to move between the cells 382, 384, and 386, it can be formed to be smaller than the channel for moving water. The communication hole 390 Through this, ice crystal nuclei generated when supercooling is canceled in any one of the plurality of cells (382, 384, 386) can spread to other cells, so that supercooling can be canceled in all cells. In a state in which the communication hole 390 and the cells 382, 384, and 386 are filled with water, the moment supercooling is canceled in any one cell, such an effect occurs through each communication hole 390 to the entire cell ( 382, 384, 386). This is because the communication hole 390 is filled with water while water is supplied to the lower tray 380.

The communication hole 390 has a cross-sectional size that does not cause significant deformation to the spherical ice, so that it can be separated from the spherical ice when the final ice is provided to the user. In the process of moving the ice, it falls into the ice bucket 600. Due to the impact generated at that time, the ice created in the spherical ice due to the communication hole 390 is separated from the spherical ice, and the spherical shape of the ice can be maintained. there is.

Meanwhile, when cold air is supplied to the ice maker 200 in a state where the lower tray 380 and the upper tray 320 are completely coupled to each other, the communication hole 390 is connected to each cell 382, 384, and 386. remain connected to each other.

Unlike FIGS. 17 and 18 , the communication hole 390 may be disposed on the upper tray 320 rather than the lower tray 380. Additionally, the communication hole 390 may be disposed on the lower tray 380 and the upper tray 320 at the same time.

Another embodiment of the present invention will be described with reference to FIG. 15.

In another embodiment, the technology prevents supercooling by lowering the temperature of the tray and supplying water to produce a small amount of ice.

As shown in Figure 15, in another embodiment, cold air is supplied to the upper tray 320 and the lower tray 380 through the duct 50. At this time, water is not supplied to the lower tray 380.

That is, because the water supply valve 740 does not open the flow path, water is not supplied to the ice maker 200. In this state, because cold air is supplied to the ice maker 200 through the duct 50, the upper tray 320 and the lower tray 380 are cooled. That is, because the lower tray 380 is cooled without water stored in it, the upper tray 320 and the lower tray 380 can be cooled to 0 degrees or less faster than when water is present.

The temperature of the upper tray 320 or the lower tray 380 is measured through the tray temperature sensor 700. At this time, it is determined whether the temperature measured by the tray temperature sensor 700 is lower than the set temperature.

At this time, the set temperature is preferably 0 degrees or lower. For example, it may mean below -10 degrees Celsius, but since ice can be formed at temperatures below 0 degrees Celsius, it is desirable to keep the temperature below 0 degrees Celsius.

If the temperature measured by the tray temperature sensor 700 is lower than the set temperature, the water supply valve 740 opens a flow path to supply water to the lower tray 380. Since the temperatures of the upper tray 320 and the lower tray 380 are considerably low, the temperature may decrease more quickly as the supplied water exchanges heat with the upper tray 320 or the lower tray 380. Therefore, ice can be created more quickly and without going through a supercooling state.

In this embodiment, the tray is cooled with cold air before water is supplied to the tray. Because water is not supplied, the temperature of the tray decreases relatively quickly. If water is supplied while the temperature of the tray is sufficiently low, the water cools quickly and does not undergo supercooling, or escapes from supercooling quickly and turns into ice. Change can happen.

After the tray has sufficiently cooled, start supplying water. When water begins to be supplied, water is supplied by the set amount without stopping the water supply. After the water supply is complete, cold air is continuously supplied to the tray to create ice. While ice is being created, no additional water is supplied, and cold air is supplied while maintaining the initially supplied amount to ultimately create ice.

Figure 19 is a diagram explaining an ice-making method according to another embodiment.

Another embodiment of the present invention will be described with reference to FIGS. 15 and 19.

In another embodiment, water is first supplied to the tray, that is, the lower tray 380, as shown in FIG. 19A. And, as shown in Figure 19b, cold air is supplied to the tray to cool the water and create ice. At this time, the tray temperature sensor 700 can measure the temperature of the tray or determine whether a specific time has elapsed to detect whether the ice has frozen.

If it is determined that the ice has frozen, water is secondarily supplied to the lower tray 380 where the ice was created, as shown in 19c. Then, because water has a greater density than ice, the ice rises and the water falls, as shown in Figure 19d.

In this state, when cold air is supplied to the ice maker 200 to cool it, crystallization proceeds centered on the ice that has already been created. Therefore, water supercooling does not occur during the process of creating ice after secondary water supply. Therefore, transparent ice can be produced.

To explain with a more specific example, approximately 10 grams of water is supplied and the ice maker is cooled. It can be detected whether the temperature of the tray measured by the tray temperature sensor 700 has reached -10 degrees Celsius or whether approximately 60 minutes have passed since the first water supply was completed. If one of the two conditions is satisfied, or both are satisfied, a secondary water supply is performed and water is supplied to the tray. At this time, in the second water supply, enough water is supplied to create spherical ice in the tray, and no additional water is supplied until the ice is discharged.

While additional water supply is in progress, the ice maker can be cooled by supplying cold air through the duct 50. When cooled sufficiently, the additionally supplied water is also cooled into ice, and spherical transparent ice can be provided to the user.

In this embodiment, because water is supplied in stages, the initially supplied water can be quickly cooled to ice, compared to a method in which water is supplied all at once to create ice. In the process of freezing ice by additional water supply, if water is supplied in the presence of ice, supercooling does not occur, so transparent ice can be provided to the user because supercooling does not occur. After the initially supplied water is converted to ice, the ice serves as a crystal nucleus, so the additionally supplied water can be phase changed to ice without being supercooled.

Of course, it is also possible to produce transparent ice by supplying water with ice initially added, rather than through a split process. The initially added ice performs the function of a crystal nucleus, so it is possible to change the phase to ice directly without going through a supercooling state during the water freezing process.

Meanwhile, the process of split water supply can be divided into primary water supply, which supplies water initially, and secondary water supply, which supplies water later. At this time, by supplying more water in the secondary water supply than in the primary water supply, it is possible to create ice more quickly in the primary water supply.

It is also possible to continuously supply cold air to the ice maker from both the primary and secondary water supplies so that the temperature of the ice maker can decrease during the process of supplying water.

Figure 20 is a diagram explaining an ice-making method according to another embodiment.

As explained with reference to FIG. 20, in the process of freezing ice while heating water by a heater, the cooling rate of the water slows down. Therefore, water cools slowly while maintaining a stable state, so supercooling can easily occur.

In a supercooled state that remains in a liquid state below the freezing point, the time for supercooling to break and change phase to ice is very short. If a phase change occurs due to a large temperature difference in a short period of time, there is a high possibility that opaque ice will be created because air cannot escape from the ice. Therefore, in order to make transparent ice, supercooling must be prevented from occurring or supercooling must be terminated at the beginning when supercooling occurs. In this embodiment, supercooling can be canceled by applying a spark discharged at high voltage to water to generate freezing nuclei and create an energy imbalance.

When a high voltage is applied between conductors that are not in contact with each other, the air, which is an insulator, loses its insulating properties and a discharge phenomenon occurs where current flows into it. A discharge spark generator 900 can be constructed using this phenomenon.

Since general water acts as a conductor, a spark can be generated on the surface of the supercooled coolant using the wire 910 connected to the discharge spark generator 900 and the electrode 920 connected to one end of the wire. The spark generated by the discharge spark generator 900 creates freezing nuclei and creates an energy imbalance in the supercooled water, effectively canceling the supercooling.

The discharge spark generator 900 may be located in the control unit of an ice maker or a refrigerator. Since a discharge spark must be applied to the exposed upper surface of the water, the electrode 920 is fixed adjacent to the position where water is supplied so as to be insulated from the upper tray 320. At this time, the upper surface of the water and the exposed electrode 920 are maintained at a distance of 1 to 3 mm so as not to contact. In addition, care is taken to ensure a distance of 5 mm or more between the upper tray 320 and the exposed electrode 920 to prevent discharged sparks from generating into the upper tray 320. The electrode 920 is disposed at the center of the opening formed in the upper tray 320 so as not to contact the opening.

The temperature of the water is measured by the tray temperature sensor 700, and when it reaches a certain supercooled temperature (-3°C to -1°C), the electrode 920 generates a spark once. If supercooling has not been terminated (0°C) by measuring the temperature of the water after a certain period of time (e.g., 5 minutes), it is possible to generate additional sparks until supercooling is terminated. It can be determined by the temperature measured by the tray temperature sensor 700 that supercooling has not been terminated.

The temperature measured by the tray temperature sensor 700 is similar to the temperature of water stored in the tray.

Additionally, if supercooling is not canceled, it is possible to continuously generate sparks at a specific cycle. At this time, the specific period may be an interval of 1 second, or an interval longer than that is also possible.

The present invention is not limited to the above-described embodiments, and as can be seen from the appended claims, modifications can be made by those skilled in the art, and such modifications fall within the scope of the present invention.

Claims (10)

An upper tray having a plurality of cells having a hemispherical shape; and
It includes a lower tray having a plurality of cells having a hemispherical shape and a communication hole connecting adjacent cells,
Water supply is performed at a water supply position where the lower tray is spaced apart from the upper tray,
After completion of water supply, the lower tray moves to the ice-making position where the lower tray is in contact with the upper tray,
While ice making is being performed at the ice making location, the communication hole limits the movement of water between cells and allows the supercooling release effect to be transmitted to other adjacent cells when supercooling of one cell is terminated. According to paragraph 1,
The ice maker is characterized in that the communication hole is disposed on the upper surface of the lower tray. According to paragraph 1,
The ice maker is characterized in that the communication hole has a semicircular cross section. According to paragraph 1,
The ice maker is characterized in that the communication hole is arranged on an extension line connecting the centers of each hemispherical cell. According to paragraph 1,
The ice maker is characterized in that the communication hole is disposed in the upper tray.


a first tray having a plurality of first cells forming part of a space in which ice is frozen;
a tray case disposed on one side of the first tray;
a tray cover disposed on the other side of the first tray; and
a second tray comprising a plurality of second cells forming another portion of the space;
The tray case, the first tray, and the tray cover are combined into a single module,
The tray case includes a heater case in which a heater is installed,
A refrigerator in which an opening including a portion corresponding to the shape of the first cell of the first tray is formed in the tray cover. According to clause 6,
A refrigerator wherein at least one of the first tray and the second tray includes a communication hole for communicating cells with each other. According to clause 6,
A refrigerator wherein the heater case is provided with an opening including a portion corresponding to the shape of the first cell of the first tray. According to clause 8,
Further comprising a pusher for separating ice from the first tray,
The pusher is a refrigerator that penetrates the opening of the heater case. According to clause 6,
a second tray case disposed on one side of the second tray;
a second tray cover disposed on the other side of the second tray; and
Further comprising a pusher to separate ice from the second tray,
The pusher presses the second tray and penetrates the second tray case.