KR100781287B1 - Ice maker and ice amount sensing thereof, and refrigerator - Google Patents

Abstract

The present invention relates to an ice making apparatus, a method for detecting ice, and a refrigerator thereof.

To this end, the present invention, ice making tray; An ice-making device that applies energy to a boundary between the ice and the ice-making tray to help discharge the ice; An ice bank in which ice discharged from the ice making tray is accommodated; Is provided in the ice tray, rotatably provided to the ice bank side, the ice detection device is limited to rotation in accordance with the interference with the ice accommodated in the ice bank; In addition, the present invention provides an ice making device including an ice making sensor that detects the amount of ice in the ice bank according to the limited rotation of the ice detecting device.

Refrigerator, ice maker, heat source, ice sensor

Description

Ice maker and ice amount sensing method, and refrigerator

1 is a perspective view showing a general ice making apparatus;

2 is a schematic view showing an operation of the ice making apparatus of FIG. 1;

3 is a schematic view showing a part of a refrigerator according to the present invention;

4 is a perspective view showing an example in which the ice making tray has one ice making chamber in the ice making apparatus according to the embodiment of the present invention;

5 is a cross-sectional view showing an example of two ice trays side by side the ice tray in the ice making apparatus according to an embodiment of the present invention;

6 is a cross-sectional view showing an example in which a rotating shaft is provided on one side of the ice making tray in the ice making apparatus according to the embodiment of the present invention;

7 is a cross-sectional view showing an example in which the heater is formed to surround one surface of the ice making tray in the ice making apparatus according to the embodiment of the present invention;

8 is a schematic view showing an example in which the heat source includes a light source or a magnetron in the ice making apparatus according to the embodiment of the present invention;

9 to 12 are schematic diagrams showing an embodiment of a full ice detection device in the ice making device according to an embodiment of the present invention.

13 is a schematic view sequentially showing an example of an ice making method of the ice making apparatus according to an embodiment of the present invention;

14A and 14B are flowcharts illustrating an ice making method and a full ice detection method of an ice making apparatus according to an embodiment of the present invention; And,

15 is a perspective view showing an example in which the ice-covering device of the present invention is applied to a conventional ice making device.

Explanation of symbols on the main parts of the drawings

100: ice maker 110: ice tray

150: heat source 170: ice detection device

190: ice bank

The present invention relates to an ice making apparatus, a method for detecting ice, and a refrigerator thereof, which can sense accurate ice and ice ice while occupying a small installation space, and are simple in structure and can separate ice from an ice making tray with a small amount of energy. will be.

A typical refrigerator is divided into a freezer compartment and a refrigerator compartment, and the refrigerator compartment is maintained at a temperature of about 3 to 4 ° C. so that food and vegetables can be kept fresh and long, and the freezer compartment has a temperature below zero to keep meat and food frozen. Is maintained.

Recently, refrigerators have an ice maker that automatically performs a series of processes related to ice making without user interaction, and an ice making device that conveniently obtains ice, and a dispenser that makes ice or water available outside the refrigerator. Various functions are added to the refrigerator for convenient use. 1 and 2 illustrate an example of an ice maker for a refrigerator, which will be described below in more detail with reference to these drawings.

The general ice making apparatus 10 includes an ice making tray 11 forming an ice making chamber in which ice is generated, a water supply unit 12 formed at one side of the ice making tray 11, and supplying water to the ice making chamber, and the ice making tray. A heater 17 mounted on the lower surface of the 11, an ejector 14 for extracting the ice generated from the ice making tray 11 to the outside, and a driving device 13 for driving the ejector 14. And an ice bank 20 for receiving and storing the ice generated by the ice making tray 11, and a full ice detection device 15 for detecting the amount of ice filled in the ice bank 20. .

The water supply unit 12 is connected to a water supply source (not shown) outside the refrigerator, and supplies water into the ice tray 11 when the ice making is required. The ice tray 11 has a substantially semi-cylindrical cross section and has partition plates for separating the ice tray into a plurality of unit chambers so that several pieces of ice of a predetermined size can be generated in the ice tray 110.

The heater 17 is mounted on the lower surface of the ice making tray 11 as shown in FIG. 2, and the ice is separated from the ice making tray 11 by heating the ice making tray 11 to melt the ice. Let it be.

The ejector 14 includes a rotating shaft installed to cross the center of the ice making tray 11 and a plurality of ejector pins 14a protruding vertically from the rotating shaft. Each ejector pin 14a is installed in a one-to-one correspondence in each unit chamber partitioned by the partition plates, so that the ice in each unit chamber is released from the ice making tray 11 as the ejector pin 14a rotates. Discharged.

On the side where the ice is taken out from the ice making tray 11, the slide 16 is inclined downward to the vicinity of the rotating shaft of the ejector 14. Accordingly, the ice discharged from the ice making tray 11 is stored in the ice bank 20 disposed under the ice making device 10 after sliding on the slide 16.

The ice detection device 15 checks the amount of ice filled in the ice bank 20 while moving in the vertical direction by the driving device 13. If the ice bank 20 is filled with ice, the ice detection device 15 may not be sufficiently lowered, thereby detecting whether the ice bank 20 is full.

The above-mentioned general ice maker for a refrigerator requires a heater, an ejector, and a driving device for the ejector to separate the ice from the ice tray. In addition, in order to detect whether or not the ice bank is full, a full ice detection device and a driving device therefor are required. Therefore, there is a problem that many components are complicated and the production cost increases.

In addition, in a typical refrigerator ice maker, the ice detection device should rotate to detect whether the ice bank is full. Therefore, a large space for the rotation of the ice detection device should be secured next to the ice tray. Therefore, the size of the ice making tray was inevitably designed to be relatively small, thereby making it impossible to produce a large amount of ice in a short time.

In addition, a general refrigerator ice maker should sufficiently heat the ice tray using the heater before the ice in the ice tray is used to spread the ice in the ice tray. This is because the ice can be separated from the ice tray without damaging the ejector and drive. Therefore, the heater must be heated for a long time, whereby a large amount of energy is consumed. In addition, since the ice melts excessively, water is also splashed together when the ice is discharged by the ejector. Water splashed out of the ice making tray is introduced into the ice bank and binds the ice in the ice bank. Thereby, there is a problem that it is difficult to automatically discharge the ice in the ice bank to the dispenser of the refrigerator.

The present invention has been made to solve the above problem, and its object is to simplify the structure of the ice making apparatus.

Another object of the present invention is to accurately determine whether the ice bank detects the full ice while making the rotation radius of the full ice detection device small.

Another object of the present invention is to improve the structure of the ice making apparatus so that a large amount of ice can be produced in a short time.

Another object of the present invention is to reduce the energy consumption of the ice making apparatus for ice-making.

Still another object of the present invention is to minimize the amount of sea ice required for ice removal to effectively prevent falling water from the ice making apparatus during ice removal.

In one aspect of the present invention for achieving the above object, an ice making tray in which ice is produced; An ice-making device that applies energy to a boundary between the ice and the ice-making tray to help discharge the ice; An ice bank in which ice discharged from the ice making tray is accommodated; Is provided in the ice tray, rotatably provided to the ice bank side, the ice detection device is limited to rotation in accordance with the interference with the ice accommodated in the ice bank; In addition, the present invention provides an ice making device including an ice making sensor that detects the amount of ice in the ice bank according to the limited rotation of the ice detecting device.

The ice-covering device may include a sensing lever installed at a lower portion of the front of the ice making tray and having a length in a length direction of the ice making tray; One side may be connected to the sensing lever, and the other side may include a sensing arm having a length toward the ice bank side.

The sensing lever may be formed to have a length corresponding to the length of the ice making tray. The sensing lever may be rotated to a position where interference with the ice is avoided before the ice is moved from the ice making tray to the ice bank, and may be rotated to the ice bank side to interfere with the ice after the ice is moved.

The sensing arm may be connected to the sensing lever in a link structure. The sensing arm may be detachably provided to the sensing lever, and the sensing arm may be provided to be variable in position along the longitudinal direction of the sensing lever. In addition, the sensing arm may be provided in plural in the sensing lever, and the sensing arms may have different lengths. The lower part of the sensing arm can also be formed branched into several branches.

The ice detection sensor may be configured to detect the rotated position of the ice detection device and measure the amount of ice accommodated in the ice bank according to whether the detected rotational position is compared with the initial position. For example, the ice detection sensor, the magnet is installed on one side of the ice detection device; And, it may be made to include a Hall sensor installed in the ice tray to correspond to the magnet.

The magnet and the hall sensor may be provided to correspond to the position close to the rotation axis of the ice sensor. The hall sensor may be provided at a position corresponding to the magnet installed in the ice detection device when the ice detection device is positioned at an initial position.

The ice tray may be rotatably provided.

The ice-making device is a method of preventing the water from falling during the rotation of the ice tray when the ice is excessively melted and the ice tray is rotated to discharge the ice, for a short time at the boundary between the ice and the ice tray. It may comprise a heat source that melts at least a portion of the interface between the ice and the ice tray by applying a high energy.

The energy supply time of the heat source may be limited until the force by the weight of the ice exceeds the binding force between the ice and the ice making tray.

The heat source includes a light source for irradiating light to at least one of the ice and the ice making tray, a magnetron for irradiating microwaves to at least one of the heat sources, or a heater disposed to be in physical contact with the ice making tray or to be separated by a predetermined distance. It can be done by.

In another embodiment of the present invention for achieving the above object, a cooling chamber; An ice making tray provided in the cooling chamber and generating ice; An ice bank in which ice discharged from the ice making tray is accommodated; Is provided in the ice tray, rotatably provided to the ice bank side, the ice detection device is limited to rotation in accordance with the interference with the ice accommodated in the ice bank; And, the ice cream of the ice bank according to the limited rotation of the ice detection device comprises a ice detection sensor, the ice detection device is installed in the front lower portion of the ice tray, A sensing lever having a length in the longitudinal direction; Then, one side is connected to the sensing lever, the other side provides a refrigerator comprising a sensing arm having a length to the ice bank side.

In another aspect of the present invention for achieving the above object, the step of driving the ice detection lever to the upper portion of the initial position before the ice is discharged from the ice making tray to the ice bank; And, after the ice is discharged from the ice tray to the ice bank provides a method of detecting the ice of the ice making device comprising the step of detecting the ice of the ice bank by driving the ice detection lever to the bottom.

The initial position may be a position where the ice detection lever is in a horizontal state on the upper side of the ice bank.

In addition, when the ice detection lever is driven downward to return to the initial position, water supply to the ice making tray may be blocked.

According to still another aspect of the present invention for achieving the above object, a cooling chamber; An ice making tray provided in the cooling chamber and generating ice; An icemaker for applying an energy to the boundary between the ice and the ice making tray to help discharge the ice from the ice making tray; An ice bank in which ice discharged from the ice making tray is accommodated; Is provided in the ice tray, rotatably provided to the ice bank side, the ice detection device is limited to rotation in accordance with the interference with the ice accommodated in the ice bank; And, the ice cream of the ice bank according to the limited rotation of the ice detection device comprises a ice detection sensor, the ice detection device is installed in the front lower portion of the ice tray, A sensing lever having a length in the longitudinal direction; Then, one side is connected to the sensing lever, the other side provides a refrigerator comprising a sensing arm having a length to the ice bank side.

Hereinafter, preferred embodiments of the present invention, in which the above object can be specifically realized, are described with reference to the accompanying drawings.

3 schematically shows a refrigerator according to the invention. The refrigerator according to the present invention has at least one cooling chamber, for example, a refrigerating chamber 1 and a freezing chamber 2. The cooling chambers comprise an evaporator 4, a compressor 3, and a cooling fan 5 for supplying cool air around the evaporator 4 to the cooling chambers. The cooling chambers may be cooled by one evaporator 4 and one cooling fan 5 or may be independently cooled by a plurality of evaporators and cooling fans. In the freezer compartment 2, an ice making apparatus 100 according to the present invention for making ice is provided.

In the ice making apparatus 100 according to the present invention, an ice making tray is rotatable unlike a general ice making apparatus. Thus, the self-weight of the ice can be used at the time of ice, thereby reducing the energy required to separate the ice from the ice tray. The ice making apparatus 100 according to the present invention is provided with an ice making device which helps discharge of ice by rotation of the ice making tray. The ice-making device independently applies heat to the boundary between the ice and the ice-making tray to effectively discharge the ice during rotation of the ice-making tray.

4 to 14 are views related to ice making apparatuses according to an embodiment of the present invention. Hereinafter, an embodiment of an ice making apparatus according to the present invention will be described in more detail with reference to these drawings.

An ice making chamber that receives water to produce ice has, for example, a semi-cylindrical shape with an open top. As shown in FIG. 4, one of the ice making chambers may be provided in one ice tray 110a, or two may be arranged in parallel in one ice tray 110b as shown in FIG. 5. Of course, a plurality of the ice making chambers may be provided in the ice making tray, or may have a shape other than a semi-cylindrical shape.

In the ice making apparatus 100 according to the present invention, there is an ice making apparatus 170 which requires a rotating radius above and below the ice bank 190 instead of the conventional ice sensing apparatus requiring a large rotating radius. Therefore, as shown in FIGS. 4 and 5, the ice trays 110a, 110b (hereinafter referred to as 110) of the ice making apparatus 100 according to the present invention can make the width much larger than that of the conventional ice making chambers. They can be placed side by side, thus producing a large amount of ice at once.

The ice making chamber is divided into a plurality of unit chambers by a plurality of partition plates protruding from the inner circumferential surface of the ice making tray 110, and thus the ice making tray 110 may make several pieces of ice at once. The partition plates are elongated along, for example, the rotation direction of the ice tray 110 so that the ice can be smoothly discharged when the ice tray 110 is rotated.

Conventional ice trays required slides to guide the ice discharged by the ejector to an ice bank disposed below the ice maker. However, the ice making apparatus 100 according to the present invention rotates the ice making tray 110 to discharge the ice in the ice making tray 110 to the ice bank 190. Therefore, since the components corresponding to the conventional slides may not be provided in the ice tray 110, the structure of the ice tray 110 is simple.

One side of the ice tray 110 is provided with a water supply unit 120 for supplying water to the ice making chamber. The water supply unit 120 is connected to an external water supply source and supplies a predetermined amount of water to the ice making chamber when ice making is required in a state where ice in the ice making tray 110 is iced.

For example, the ice tray 110 may be installed to rotate about an axis 131 disposed at the center thereof, as shown in FIGS. 4 and 5, or at one side thereof as shown in FIG. 6. It may be installed to rotate about the axis (131a) disposed. When the shaft 131a of the ice making tray 110 is disposed at one side of the ice making tray 110, the rotation radius of the ice making tray 110 is increased.

In order to rotate the ice tray 110, a driving device 130 is provided at one side of the ice tray 110. The driving device 130 includes a motor (not shown) connected to a driving shaft (not shown) substantially coaxial with the shaft 131, and the ice making tray 110 is connected to the driving shaft. The driving device 130 may be configured to rotate the ice tray 110 in a forward direction and a reverse direction, or continuously rotate in one direction.

In addition, the driving device 130 rotates the detection lever 171 of the ice detection device 170. That is, the driving device 130 is provided with a motor (not shown) connected to a drive shaft (not shown) coaxial with a rotation axis (not shown) of the sensing lever 171, and one end of the sensing lever 171. Is connected to the drive shaft. The driving device 130 may be configured to rotate the sensing lever 171 in the forward direction and the reverse direction.

In this case, the ice making tray 110 and the ice-covering device 170 may be driven by separate motors, or may be driven by one motor.

In order to prevent the wires connecting the driving device 130 and the components that may be mounted on the ice making tray 110 by twisting the ice tray 110, the motor of the driving device 130 is positive. It is desirable to be able to reverse. Meanwhile, the driving device 130 may include a step motor configured to rotate the ice making tray 110 in a forward or reverse direction by a predetermined angle, for example, 180 ° or 90 °.

The ice tray 110 may be detachably connected to the driving device 130. Then, ice trays having various shapes and ice making capacities can be selectively mounted and used. Therefore, not only the user's taste can be satisfied, but also the amount of one-time ice making can be adjusted appropriately.

The ice making apparatus 100 according to the embodiment of the present invention supplies thermal energy to the boundary between the ice and the ice making tray 110 to help the ice. To this end, the ice making apparatus 100 may be provided with heaters 150a and 150b (hereinafter referred to collectively as 150). The heater 150 may be mounted to be in physical contact with the ice making tray 110 or may be disposed away from the ice making tray 110 by a predetermined distance. For reference, FIGS. 4 to 6 illustrate an example in which the heater 150a is disposed to cross the bottom surface of the ice making tray 110.

As shown in FIG. 7, the heater 150b may be disposed to surround one surface, for example, a bottom surface of the ice making tray 110. In this case, the heater 150b may be formed of a conductive polymer, a plate heater with positive thermal coefficient, an aluminum thin film, and other heat transfer materials. Although not shown, the heater 150 may be embedded in the ice tray 110 or may be provided on an inner surface of the ice tray 110. Furthermore, at least a part of the ice making tray 110 may be configured to perform a role of the heater by being made of a heat generating resistor when electricity is applied.

As another example, the ice making apparatus 100 may include a heat source, which is different from the heater, which is disposed away from the ice making tray 110 as shown in FIG. 8. Examples of the heat source include a light source 150c for irradiating light to at least one of the ice and the ice making tray 110 or a magnetron 150d for irradiating microwaves to at least one of the ice and the ice making tray. Can be done.

As described above, a heat source such as a heater, a light source, or a magnetron applies at least one of the ice and the ice making tray 110 or a boundary thereof to the at least one portion of the ice and the ice making tray 110. Melt it slightly. Accordingly, when the ice tray 110 is rotated, the ice is separated from the ice tray 110 by its own weight even when the boundary surface is not thawed.

Therefore, according to the present invention, since the ice can be performed even if a small amount of energy is input than the conventional ice making device, the energy consumption can be reduced. Of course, since the amount of thawing is small, less water is generated during ice-taking, thereby effectively preventing water from falling from the ice making tray 110 to the ice bank 190 during ice-taking.

On the other hand, when the heat source is arranged to heat the ice tray 110, the ice tray 110 is gradually heated to melt the interface with the ice. However, the portion adjacent to the heat source of the interface melts quickly and much, while the portion away from the heat source melts late and less. Therefore, even if the ice making tray 110 is inverted and iced using the own weight of the ice, it is difficult to completely prevent the occurrence of excessive excessive sea ice on the interface.

Therefore, in order to effectively prevent the ice melts excessively and the water falls during the rotation of the ice tray 110, a method and time for supplying the thermal energy supplied to the interface between the ice and the ice tray 110, etc. It would be desirable to control appropriately.

To this end, the present invention proposes to apply high energy to the boundary between the ice tray 110 and the ice in a short time. For example, when a high voltage is instantaneously applied to the heater 150 for heating the ice making tray 110, the heater 150 instantly generates a high temperature and thus the ice making tray 110 is also instantaneously heated. At least partly melts the interface between the ice and the ice tray. At this time, if the ice tray 110 is already rotated or rotates, the ice is separated from the ice tray 110 by its own weight before the boundary surface is locally excessively thawed. Therefore, it is possible to effectively prevent water from falling during the rotation of the ice tray 110 by excessive thawing of ice.

When high heat energy is applied to the interface between the ice and the ice making tray 110 in a short time, the ice may be removed from the ice making tray 110 with the minimum amount of thawing required for the ice using its own weight as described above. Can be separated. However, if the supply time of the thermal energy is not properly limited, the ice making tray 110 may be heated more than necessary even after the ice is discharged, resulting in excessive consumption of power and heat loss.

Therefore, it is preferable that the supply time of the thermal energy is limited to until the force by the weight of the ice exceeds the binding force of the ice making tray. In other words, even if the interface between the ice and the ice making tray 110 is not completely melted, the supply time of the thermal energy is limited until the ice is forcibly separated by its own weight.

To this end, it may be controlled to supply heat energy only during the optimal heat energy supply time obtained experimentally, or the supply time of the heat energy may be controlled by detecting a change in weight of the ice making tray 110. As such, when the time of applying high thermal energy to the boundary between the ice and the ice making tray 110 in a short time is controlled, the minimum amount of thawing required for separation by the self-weight of the ice is obtained. It is possible to effectively prevent the occurrence of falling water during the rotation of the tray 110. Of course, heat loss and waste of power can also be prevented.

On the other hand, the ice making apparatus according to the present invention may detect whether the ice bank 190 is full while the detection lever 171 of the ice sensing device 170 is rotated. In more detail, the sensing lever 171 is rotated to the top to avoid interference with the ice in the initial position in the horizontal state before the ice, and rotated to the lower after the ice. At this time, when the sensing lever 171 rotates smoothly and returns to the horizontal state of the initial position, the ice bank 190 is not in a full state but is moved to the horizontal state of the initial position by interference with ice in the ice bank 190. If it does not return, the ice bank 190 detects that it is full.

To this end, for example, a magnet may be installed on the sensing lever 171 of the ice sensing device 170, and a hall sensor may be installed on the outside of the driving motor so as to correspond to another fixed side, that is, the magnet. In this case, the magnet and the hall sensor may be provided to correspond to the position close to the rotation shaft of the sensing lever 171. In addition, the hall sensor may be provided at a position corresponding to the magnet installed in the sensing lever 171 when the sensing lever 171 is positioned at an initial position. Then, as the sensing lever 171 rotates, the relative position between the hall sensor and the magnet changes according to the degree of interference between the sensing arm 172 and the ice contained in the ice bank 190, and accordingly, the output from the hall sensor is output. It is possible to determine whether the ice bank 190 is full based on the strength of the voltage.

9 to 12 illustrate various embodiments of the ice-covering device 170 applied to the ice making apparatus 100 according to the embodiment of the present invention.

Hereinafter, the ice detection device 170 will be described with reference to these drawings.

As shown in FIGS. 9 to 12, the ice-covering device 170 applied to the ice making device 100 according to the embodiment of the present invention uses the sensing lever 171 and the sensing arm 172 as described above. It is made to include.

The sensing lever 171 is rotatably fixed at one side to an outer surface of the drive motor 130, and is installed at the front lower portion of the ice making tray 110 to have a length in the longitudinal direction of the ice making tray 110. . In this case, the sensing lever 171 may be formed to have a length corresponding to the length of the ice making tray 110.

The sensing arm 172 is installed in the sensing lever 171 in a link structure through a through hole 171a to enable horizontal flow, and has a length toward the side of the ice bank 190. It has a structure extending to the bottom of.

Accordingly, the ice sensor 170 may determine whether the ice bank 190 is full of ice, while the detection lever 171 is rotated so that the detection arm 172 is provided with the ice accommodated in the ice bank 190. It is determined whether the ice bank 190 is full based on the degree of interference.

As shown in FIG. 10, a plurality of through holes 171a formed in the sensing lever 171 are formed, and the sensing arm 172 is detachably configured to adjust the degree of full ice of the ice bank desired by the user.

That is, the sensing arm 172 is connected to and installed in any one of the plurality of through holes 171 a, and the sensing arm detects the full ice of the ice bank 190 as the through holes 171 a are connected to each other. By varying the height of the ice interference of the 172, the ice bank 190 can adjust the amount of ice that is iced.

For example, when a large amount of ice is required, such as in summer, the sensing arm 172 is installed in the through hole 171a formed at the leftmost side of the sensing lever 171 to sense the ice bank 190. By increasing the interference height, the amount of ice stored in the ice bank 8 is increased, and when a small amount of ice is required, such as winter, the detection arm is formed in the through hole 171a formed at the rightmost side of the detection lever 171. By installing 172 to lower the interference height for detecting the ice of the ice bank 190, it is possible to reduce the amount of ice stored in the ice bank 190.

As described above, the ice level of the ice bank 190 may be adjusted according to a user's taste or environment, thereby reducing power consumption required for the operation of the ice making apparatus.

As shown in FIG. 11, a sensing arm 172 is installed in each of the plurality of through holes 171a formed in the sensing lever 171 to perform ice detection of the ice bank 190 in a wider area so that a more accurate ice bank ( It is also possible to perform the ice detection of 190).

In this case, the plurality of sensing arms 172 may have different lengths.

As shown in FIG. 12, instead of forming a plurality of sensing arms 172 installed in the through-hole 171a of the sensing lever 171, the lower portion of the sensing arm 172 is formed into a branched shape into ice. The ice detection area of the bank 190 may be expanded to perform more accurate ice detection of the ice bank 190.

13 illustrates an example of an ice making method of the ice making apparatus 100 according to the embodiment of the present invention described above, FIG. 14A shows a specific application example, and FIG. 14B illustrates an ice making apparatus according to an embodiment of the present invention. The ice detection method of 100) is shown. Hereinafter, the ice making method and the ice detection method will be described with reference to these drawings.

If ice making is required, the ice making apparatus 100 is turned on and the ice making operation is started. When the ice making operation is started, as shown in FIG. 9, the water supply unit 120 supplies water to the ice making chamber of the ice making tray 110. When the supply of water is completed, the water in the ice making tray 110 is exposed to cold air in the cooling chamber for more than a predetermined time and is frozen. (S 102) When the temperature of the ice making tray 110 is lowered to a predetermined temperature or less (S 103), and after a predetermined time after the water supply, it is determined that ice making is completed and the process for ice-making is started.

To drive the ice, the driving device 130 rotates the ice tray 110 in the forward direction. 9 illustrates an example in which the ice tray 110 is rotated 180 °, but the ice tray 110 may be rotated at an angle of less than or more. In other words, the ice tray 110 may be rotated to a position where ice in the ice tray 110 can be separated from the ice tray 110 by itself.

After the ice making is completed, the high voltage is applied to the heater 150 for a short time as described above before, during, or after the ice making tray 110 rotates. (S 105) Then, the ice in the ice tray 110 is stored in the ice bank 300 away from the ice tray 110 by its own weight without excessive thawing as shown in FIG. 9. When the ice is completed, the ice tray 110 is rotated in the reverse direction to return to the original position. (S 106)

When the ice tray 110 returns, it is determined whether the ice bank 300 is in an iced state. (S 200) If the ice bank 300 is not full ice, the ice tray 110 is returned to its original position, the water supply is again supplied to the ice tray 110, and the ice bank 300 is repeatedly performed as described above. De-icing continues until) is full of ice.

It is determined whether the ice making apparatus 100 is turned off while the ice bank 300 is in full ice. (S 108) If the ice making apparatus 100 is turned off, all the ice making operations are completed, but if the ice making apparatus 100 is not turned off and the ice making request continues, the ice making apparatus 100 waits for a predetermined time. (S 109) After waiting for a predetermined time, the ice tray 110 is rotated again to detect whether the ice is full (S 107), and the above processes are performed according to the result.

On the other hand, the determination of the ice state of the ice bank 190 (S 200) drives the sensing lever 171 to the initial position and the drive from the initial position to the upper position before the ice is started (S 201, S 202). Then, after the completion of the ice (S 203), the sensing lever 171 is driven to the lower (S 204). Then, the sensing arm 172 to the degree of interference with the ice accommodated in the ice bank 190 Accordingly, the rotation of the sensing lever 171 is limited. That is, it is determined whether the sensing lever 171 returns to the initial position to determine whether the ice bank 190 is full. (S 205) If the ice bank 190 is full, water supply is stopped and ice making is performed. The device off determination step (S 108) is performed, and if the ice bank 190 is not full, it returns to the water supply step (S 101).

Meanwhile, FIG. 15 illustrates an embodiment in which the ice-covering device 170 of the present invention is applied to an ice making device for performing an ice by a conventional ejector. The ice-making device is the same as the conventional one, and the ice-covering device 170 is described above. Since the embodiments and the structure and the control method are the same, a detailed description thereof will be omitted.

Although several embodiments have been described above, it will be apparent to those skilled in the art that the present invention may be embodied in many other forms without departing from the spirit and scope thereof.

Accordingly, the described embodiments are to be considered as illustrative and not restrictive, and all embodiments within the scope of the appended claims and their equivalents are included within the scope of the present invention.

As described above, according to the present invention, the structure of the ice making tray and the structure required for full ice detection are very simple. Therefore, manufacturing can be easily performed, manufacturing costs can be reduced, and ice detection can be made more accurate.

In addition, since the width of the ice tray can be designed to be much larger than that of the related art, the capacity of one ice maker can be increased. Thus, a large amount of ice can be produced in a short time.

Furthermore, since the thermal energy is supplied to the boundary between the ice and the ice making tray, and in addition to using the self-weight of the ice, it can be iced with less energy than before.

Furthermore, by supplying a large amount of energy to the boundary between the ice and the ice tray for a short time, it is possible to obtain the minimum amount of thawing required for the ice breaking, thereby preventing excessive thawing and falling water during the ice tray rotation.

Claims (23)

An ice making tray for producing ice; An ice-breaking device for performing ice-making by applying energy to the boundary between the ice and the ice-making tray; An ice bank in which ice iced from the ice making tray is accommodated; A sensing lever provided to be rotatable about a rotation shaft formed in a length direction substantially downward with a length direction of the ice making tray; It is installed at any one of a plurality of installation positions provided at predetermined intervals in the longitudinal direction of the detection lever to detect the different amount of ice for each installation position, the installation position disposed close to the rotation shaft of the detection lever A sensing arm which, when installed, increases the amount of ice during full ice; And An ice making apparatus comprising an ice-covering sensor for detecting the amount of ice in the ice bank according to the degree of rotation of the detection lever. The method of claim 1, The sensing lever includes a through hole provided in each installation position provided at a predetermined interval in the longitudinal direction, And the sensing arm is selectively coupled to the through hole at each of the installation positions. The method of claim 1, And the sensing lever is formed to have a length corresponding to the length of the ice tray. The method of claim 1, And the sensing lever is rotated to a position where interference with the ice is avoided before the ice is moved from the ice making tray to the ice bank, and is rotated to the ice bank side to interfere with the ice after the ice is moved. The method of claim 1, And the sensing arm is connected to the sensing lever in a link structure. The method of claim 2, And the sensing arm is detachably provided in the through hole. The method of claim 2, And the sensing arm is rotatable about the through hole. The method of claim 1, An ice making apparatus, characterized in that the lower portion of the sensing arm is formed by diverging into several branches. The method of claim 1, The ice sensor detects the rotated position of the ice sensor, and measures the amount of ice accommodated in the ice bank according to whether the detected rotation position and the initial position is compared. The method according to claim 1 or 9, The ice sensor, A magnet installed on one side of the ice detection device; And, Ice making device comprising a Hall sensor installed on the side of the fixing part corresponding to the magnet. The method of claim 10, And the magnet and the hall sensor correspond to each other in a position proximate to the rotation shaft of the sensing lever. The method of claim 10, And the hall sensor is provided at a position corresponding to the magnet when the sensing lever is positioned at an initial position. The method of claim 1, The ice making apparatus is characterized in that the ice tray is rotatably provided. The method of claim 1, The moving device, When the ice is excessively melted and the ice tray is rotated to discharge the ice, high energy is applied to the boundary between the ice and the ice tray for a short time to prevent water from falling during the rotation of the ice tray. An ice making device comprising a heat source for melting at least a portion of the ice and the interface of the ice tray. The method of claim 14, The heat source includes a light source for irradiating light to at least one of the ice and the ice making tray, a magnetron for irradiating microwaves to at least one of the heat sources, or a heater disposed to be in physical contact with the ice making tray or to be separated by a predetermined distance. Ice making device. The method of claim 1, And a control unit for controlling the detection lever and controlling an amount of ice making through the ice making tray and an amount of ice making through the ice making device according to the information received from the ice detection sensor. An ice making tray for producing ice; An ice-breaking device for performing ice-making by applying energy to the boundary between the ice and the ice-making tray; An ice bank in which ice iced from the ice making tray is accommodated; A sensing lever provided to be rotatable about a rotation shaft formed in a length direction substantially downward with a length direction of the ice making tray; Sensing arms which are respectively installed at a plurality of installation positions provided at predetermined intervals in the longitudinal direction of the sensing lever, and the length of which is shorter from the rotation shaft side of the sensing lever toward the end; And An ice making apparatus comprising an ice-covering sensor for detecting the amount of ice in the ice bank according to the degree of rotation of the detection lever. Cooling chamber; An ice making tray provided in the cooling chamber and generating ice; An ice-breaking device for performing ice-making by applying energy to the boundary between the ice and the ice-making tray; An ice bank in which ice iced from the ice making tray is accommodated; A sensing lever provided to be rotatable about a rotation shaft formed in a length direction substantially downward with a length direction of the ice making tray; It is installed at any one of a plurality of installation positions provided at predetermined intervals in the longitudinal direction of the detection lever to detect the different amount of ice for each installation position, the installation position disposed close to the rotation shaft of the detection lever A sensing arm which, when installed, increases the amount of ice during full ice; And And a freezing sensor configured to detect the amount of ice in the ice bank according to the degree of rotation of the detection lever. The method of claim 18, The sensing lever includes a through hole provided in each installation position provided at a predetermined interval in the longitudinal direction, And the sensing arm is selectively coupled to the through hole at each installation position. The method of claim 19, And the sensing arm is detachably provided in the through hole. The method of claim 19, And the sensing arm is rotatable about the through hole. Cooling chamber; An ice making tray provided in the cooling chamber and generating ice; An ice-breaking device for performing ice-making by applying energy to the boundary between the ice and the ice-making tray; An ice bank in which ice iced from the ice making tray is accommodated; A sensing lever provided to be rotatable about a rotation shaft formed in a length direction substantially downward with a length direction of the ice making tray; Sensing arms which are respectively installed at a plurality of installation positions provided at predetermined intervals in the longitudinal direction of the sensing lever, and the length of which is shorter from the rotation shaft side of the sensing lever toward the end; And And a freezing sensor configured to detect the amount of ice in the ice bank according to the degree of rotation of the detection lever. delete

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