KR100565602B1 - ice-making apparatus in the refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator, and more particularly to an ice maker of the refrigerator to shorten the ice making speed.

To this end, the present invention is one side portion is rotatably supported in the freezer compartment or door, the ice tray has an ice making mold therein, the thermal conductivity and is formed of a flexible metal material so that it can be twisted; A pleated stress relaxation portion (52a) formed in a predetermined portion where the stress of the ice tray is concentrated when the ice tray is twisted; It is connected to the other side of the ice making tray and transmits a driving force, and as the ice making tray is twisted by the driving force, ice is separated from the ice making tray, and the ice making tray is rotated to rotate the ice in the ice making chamber to the ice bank. It provides a refrigerator ice maker including a motor unit 60 for discharging.

Refrigerator, ice maker

Description

Ice-making apparatus in the refrigerator

1 is a schematic view showing a state in which an ice maker is installed in a conventional refrigerator.

2 is a perspective view showing the structure of an ice maker constituting the ice making device of FIG.

Figure 3 is a side view showing the structure of the ice maker and the ice bank in the refrigerator of Figure 1;

Figure 4 is a state diagram showing the process of the ice produced in the ice maker of Figure 3 accommodated in the ice bank.

5 is an exploded perspective view showing an ice maker of a refrigerator according to the present invention.

6A is a perspective view illustrating an embodiment of an ice cube forming the ice tray of FIG. 5.

6B is a perspective view illustrating another embodiment of an ice cube forming the ice tray of FIG. 5.

7 is an operation state diagram showing a process of separating the ice by twisting the ice tray in the ice maker of FIG.

FIG. 8 is an operating state diagram illustrating a state in which ice is discharged to an ice bank by rotating an ice tray in the ice maker of FIG. 5; FIG.

Explanation of symbols on the main parts of the drawings

50: ice tray 51: ice tray

52: compartment rib 52a: stress relief portion

53: guide portion 54: shaft fastening portion

61: motor portion 61a: rotating shaft

62: support panel 63: rotation guide hole

64: support rib

The present invention relates to a refrigerator, and more particularly, to an ice making apparatus of a refrigerator to shorten the ice making speed.

A typical refrigerator is divided into a freezer compartment and a refrigerator compartment. The refrigerating chamber keeps food and vegetables fresh and long at a temperature of about 3 ° C. to 4 ° C., and the freezing chamber keeps food such as meat or fish frozen at subzero temperatures.

Recently, various functions have been added to the refrigerator for the user to conveniently use, such as storing kimchi. The ice making machine described below is one such additional function.

Hereinafter, a conventional refrigerator ice making apparatus will be described with reference to FIGS. 1 to 4.

1 is a schematic view showing a state in which a conventional ice maker is installed in the refrigerator, Figure 2 is a perspective view showing the structure of the ice maker constituting the ice maker of Figure 1, Figure 3 is a structure of the ice maker and ice bank in the refrigerator of Figure 1 Figure 4 is a side view, Figure 4 is a state diagram showing a process in which the ice produced in the ice maker of Figure 3 is accommodated in an ice bank.

Referring to FIG. 1, the refrigerator is divided into a freezer compartment and a refrigerating compartment, and a door 1 is installed to open and close the freezer compartment and the refrigerating compartment. An ice maker is installed in the freezer compartment, and a control panel (not shown) is installed on an outer surface of the door 1 to allow a user to select a predetermined function of the refrigerator.

The ice maker includes a ice maker 10 for producing ice, an ice bank 20 for accommodating the produced ice, and a dispenser 2 for discharging the ice of the ice bank to the outside. In this case, the ice maker and the ice bank are installed in the freezer compartment, and the dispenser is installed in the door.

2 and 3, the ice maker 10 has an ice making chamber 11 in which ice is generated and a water supply part 12 formed at one side of the ice making chamber 11 to supply water to the ice making chamber. Is formed. The ice maker is made of a metallic material to improve the cold and thermal conductivity of the freezer compartment.

In the ice making chamber 11, partition ribs 11a are formed to protrude upward at predetermined intervals so that ice can be separated. In addition, a fastening portion 15 is formed at a rear predetermined portion of the ice making chamber 11 so as to fix the ice maker to the freezing chamber.

The motor unit 13 is installed at one side of the ice making chamber 11. The motor unit 13 has a built-in motor, the ejector 14 (ejector) is rotatably connected to the rotating shaft of the motor.

The ejector 14 is installed so that the rotation axis crosses the center of the ice making chamber 11, and a plurality of ejector pins 14a are spaced apart at predetermined intervals so that the rotation axis of the ejector is substantially perpendicular to the rotation axis. At this time, each of the ejector pin 14a is disposed for each section partitioned by the partition ribs 11a.

As the ejector 14 is rotated by the motor unit 13, the ejector pin 14a discharges the ice to the ice bank 20.

In addition, a plurality of slide bars 16 extend in the upper upper end portion of the ice making chamber 11 to about the rotation axis of the ejector 14.

A heater 17 (see FIG. 4) is attached to the bottom surface of the ice making chamber 11. The heater 17 heats the surface of the ice making chamber for a short time to slightly dissolve the ice surface attached to the surface of the ice making chamber so that the ice can be easily separated from the ice making chamber 11.

The ice maker 10 is provided with an ice sensing arm 18 to measure the amount of ice filled in the ice bank 20.

The ice bank 20 has an upper surface open to receive falling ice and an ice outlet 21 is formed in a predetermined portion of the lower surface. The ice outlet 21 is formed at a position corresponding to the dispenser 2.

In addition, the ice bank 20 is provided with an auger 22, a motor device 23, an ice grinder 30, and an ice discharger 40.

The auger 22 is formed in a threaded form and is rotatably coupled with the motor device 23.

Accordingly, when the motor device 23 is rotated, the ice is moved to the ice grinder 30 as the auger 22 is rotated.

The ice grinder 30 is composed of a housing 31, a fixed blade 32 and a movable blade 33.

At this time, the housing 31 is formed in a cylindrical shape with one end open. The fixed blade 32 is fixed inside the housing 31 so as to cross the inside of the housing, and an end portion of the auger 22 is inserted into the center of the fixed blade 32 to serve as a rotating shaft portion, and the end of the auger. At least one movable blade 33 is provided in the part. This movable blade 33 is arranged between the stationary blades 32.

In addition, the ice discharger 40 is composed of a shutter 41 and a solenoid 42.

That is, a substantially plate-shaped shutter 41 is provided at the ice outlet 21 of the housing 31 so as to open and close the ice outlet 21 at a predetermined opening degree, and the solenoid 42 is provided at the shutter 41. Is connected. Here, the shutter 41 discharges the ice that is not crushed by the crushed ice pieces or blades (hereinafter referred to as “ice ice”) to the dispenser 2 by adjusting the opening degree of the ice outlet 21.

A dispenser 2 having a predetermined space is installed below the ice outlet as shown in FIG. 1. The dispenser 2 is formed to communicate the ice bank 20 with the outside. At this time, the dispenser (2) is not shown, but when the ice is not discharged, the device is installed to block the outside air.

Referring to the operation of the icemaker of the conventional refrigerator configured as described above are as follows.

When the ice bank 20 determines that the ice bank 20 lacks ice by the ice detection arm 18, water is supplied to the water supply part 12 of the ice maker 10. This water is filled up to a predetermined level in the ice making chamber 11 and is frozen by cold air in the freezing chamber.

When the ice is manufactured, the heater 17 of the ice maker is operated for a short time to melt the contact surface of the ice in contact with the surface of the ice making chamber 11. Subsequently, as the ejector pin 14a is rotated by the motor unit 13, the ice of the ice maker is discharged to the ice bank 20 as shown in FIG. 4.

When the ice bank 20 is filled with a predetermined amount of ice by repeating this series of processes, the ice making process of the ice maker 10 is terminated by the control unit. In addition, if it is determined that the ice is insufficient in the ice detection arm 18, the ice making process is performed again.

When the user selects a predetermined button on the control panel while the ice bank 20 is filled with ice, the ice or crushed ice is discharged to the dispenser 2 by opening and closing the shutter at a predetermined opening degree. . Accordingly, users can selectively obtain ice cubes and crushed ice.

However, the icemaker of the refrigerator has the following problems.

First, the ice maker dissolves ice in the ice bank by rotating the ejector after melting the ice slightly on the surface of the ice making chamber. Therefore, there is a problem that the deicing time is inevitably delayed by a time for heating the ice making chamber with the heater, a time for cooling the heated ice maker again.

Second, since the ice maker must go through a process of melting the ice surface by the heater, more power is consumed to operate the heater. In addition, since the temperature of the freezer compartment is increased when the heater is operated, power is consumed to recool the freezer compartment.

Third, when the temperature of the freezer compartment increases as the heater is operated, the temperature change range of the freezer compartment increases. Therefore, there is a problem that it is difficult to control the temperature of the freezer compartment within a certain temperature range.

In order to solve the above problems, it is an object of the present invention to provide an ice maker of the refrigerator that can shorten the ice making time.

In order to achieve the above object, the present invention is one side portion is rotatably supported in the freezer compartment or door, and has an ice making mold therein, the ice making tray is formed of a flexible metal material to be twisted and thermally conductive; A pleated stress relaxation portion formed in a predetermined portion where the stress of the ice making tray is concentrated when the ice making tray is twisted; It is connected to the other side of the ice making tray and transmits a driving force, and as the ice making tray is twisted by the driving force, ice is separated from the ice making tray, and the ice making tray is rotated to rotate the ice in the ice making chamber to the ice bank. It provides a refrigerator ice maker including a motor unit for discharging.

In the icemaker of the refrigerator according to the present invention, the same parts as in the prior art are given the same reference number, and the description of the same configuration and operation will be omitted.

Hereinafter, an embodiment of an ice maker according to the present invention will be described with reference to FIGS. 5 to 7.

5 is an exploded perspective view showing an ice maker of the refrigerator according to the present invention, Figure 6a is a perspective view showing an embodiment of the ice making cube constituting the ice tray of Figure 5, Figure 6b is an ice making constituting the ice tray of Figure 5 7 is a perspective view showing another embodiment of the cube, Figure 7 is an operating state showing the process of separating the ice by twisting the ice tray in the ice maker of Figure 5, Figure 8 is an ice bank by rotating the ice tray in the ice maker of Figure 5 It is an operation state diagram showing the state to discharge | emitted by the.

An ice maker is installed in a freezer compartment or a door of the refrigerator, and the ice maker includes an ice maker tray 50 and a motor unit 60.

The ice tray 50 is rotatably supported at one side of the freezing chamber or the door, an ice making chamber is formed therein, and is formed of a flexible metal material to be twisted and thermally conductive. At this time, it is preferable to form a pleated stress relief portion 52a at a predetermined portion where stress is concentrated when the ice tray is twisted.

One side of the ice tray 50 is rotatably supported in a freezing compartment or a door, and an ice making chamber is formed therein.

Since the ice tray 50 is made of a metallic material, it improves the thermal conductivity of cold and water in the freezer compartment. Of course, it is also understood that the ice making tray may be formed of a predetermined portion of a metal material and a predetermined portion of a synthetic resin material.

In this case, a support panel 62 is installed near one side of the ice tray 50, and one side of the ice tray 50 is rotatably supported by the support panel 62.

In more detail, a guide portion 53 protrudes from one side of the ice making tray 50, a rotation guide hole 63 is formed in the support panel 62, and the guide portion 53 is It is inserted into the rotation guide hole (63). Here, the rotation guide hole 63 is formed to guide the movement path of the guide portion 53 when the ice tray is rotated.

The motor unit 60 is connected to the other side of the ice making tray and transmits a driving force, and as the ice making tray 50 is twisted by the driving force, ice is separated from the ice making tray, and the ice making tray is rotated to remove the ice. Drain the ice from the ice chamber into the ice bank.

At this time, the shaft fastening portion 54 is formed on the other side of the ice making tray 50 at the rear side of the main body so that the rotating shaft (61a) of the motor unit 60 is connected, the ice tray 50 One side portion of the guide portion 53 is formed at a position that is weighted toward the rear side of the main body.

Therefore, the guide shaft 53 and the rotating shaft 61a of the motor unit are positioned in the diagonal direction of the ice making tray, so that the ice making tray 50 can be twisted using less force.

In addition, the rotation guide hole 63 is formed in a substantially semi-circular shape having a radius r from the rotation axis of the ice making tray 50 to the guide portion 53. The rotation guide hole 63 is formed to have a width W1 slightly larger than the size of the guide 53 so that the guide 53 can slide smoothly.

On the other hand, it is preferable to form a support rib 64 at the corner of the main body rear side of the support panel 62 so as to support the edge of the ice making tray 50. This is to allow the concentrated load generated when the ice tray 50 is twisted to be distributed to the guide portion 53 and the support rib 64.

Here, the guide portion 53 of the ice making tray preferably has a predetermined strength so as to withstand the concentrated load applied when the ice making tray is twisted.

A predetermined number of ice cubes 51 are formed in the ice-making chamber of the ice tray 50 by the partition ribs 52, and a pleated stress relief portion 52a is formed at the corner of each ice cube 51. Is formed.

At this time, the stress relief portion 52a is formed in the side edge portion and the bottom edge of each ice cube 52 as shown in Figure 6a, or as shown in the side edge portion of each ice cube, as shown in Figure 6b It may be formed. Of course, it can be understood that the bottom surface of each ice cube may be formed only at the corners. In addition, it is understood that the stress relaxation portion of each ice cube may be formed on the side and bottom edges of the ice cube, as well as the side edges and the bottom edges.

Here, the ice-making cube 52a is formed in a substantially rectangular cross section as shown, but may be variously modified, such as a circular cross section, and the shape of the stress relief part may also be variously modified without being limited to a wrinkle shape. It is also understandable.

In addition, since the ice making tray can be changed into various shapes, it can be understood that the stress relaxation part 52a may also be formed at a portion where stress is concentrated in the changed ice making tray.

Referring to the operation of the ice maker configured as described above is as follows.

When it is determined that the ice is insufficient by the control unit of the refrigerator, the ice tray 50 is filled with water to a certain level. The water thus filled is quickly cooled by being in thermal contact with the ice making tray and directly in thermal contact with the cold of the freezer compartment. In this process of making ice, ice is attached to the surface of the ice-making chamber.

Subsequently, as the motor unit 61 is rotated by a predetermined angle, the ice making tray 50 is constantly twisted as shown in FIG. 7. As the ice tray is twisted in this way, the ice is separated from the ice tray. In this case, since each stress cube is formed in each ice cube of the ice tray, stress concentration may be prevented from being concentrated at an edge portion even if the ice tray is twisted.

The support rib 64 formed on the support panel 62 distributes the load concentrated on the guide portion 53 of the ice tray by supporting a predetermined edge portion of the ice tray 50.

When ice is separated from the ice making tray 50 through this process, the motor unit 60 rotates the ice making tray 50 to the other side. Accordingly, the guide part 53 slides along the rotation guide hole 63.

When the ice tray 50 is inverted as shown in FIG. 8, ice of the ice tray falls into the ice bank.

By repeating this series of steps, if the ice bank is filled with a certain amount of ice, the ice making process of the ice maker is completed. In addition, if it is determined that the ice bank lacks ice, ice is produced through the ice making process as described above.

As described above, the ice maker of the refrigerator according to the present invention has the following effects.

First, since the ice making tray is made of a flexible thermal conductive material, water is injected while the ice making tray is cooled in advance. Accordingly, there is an effect that can shorten the time to produce ice.

Second, since there is no need to use a heater as in the prior art to separate the ice from the ice tray, there is an effect that can reduce the time and power consumption required to heat and cool the ice tray.

Third, since the heater is not installed in the ice maker as in the prior art, it is easy to control the temperature of the freezing chamber within a predetermined range.                     

Fourth, since the ice maker does not need to separately install a device such as a rejector to discharge ice as in the related art, the structure of the ice maker can be simplified.

Claims (7)

An ice making tray having one side rotatably supported in the freezing chamber or the door, the ice making mold having an ice making mold therein, and having a thermal conductivity and a flexible metal material to be twisted; A pleated stress relaxation portion formed in a predetermined portion where the stress of the ice making tray is concentrated when the ice making tray is twisted; And, It is connected to the other side of the ice tray to transfer the driving force, the ice tray is distorted by the driving force to separate the ice from the ice tray, and rotate the ice tray to discharge the ice in the ice compartment in the ice bank Motor unit: ice maker of the refrigerator comprising a. The method of claim 1, A support panel is installed near one side of the ice making tray, and one side of the ice making tray is rotatably supported on the support panel. The method of claim 2, A guide part protrudes from one side of the ice making tray, and a guide part is inserted into the support panel, and a rotating guide hole is formed to guide a moving path of the guide part of the ice making tray. The method of claim 3, wherein A guide part is formed at a position that is weighted toward the rear side of the main body on one side of the ice making tray, and a rotation shaft of the motor device is connected to a position that is weighted toward the door side on the other side of the ice making tray, and the rotating shaft of the ice making tray is connected to the support panel. The ice maker of the refrigerator in which the rotation guide hole which makes the distance from the guide part to a radius is formed. The method of claim 4, wherein And a support rib formed on the support panel to support an inner edge of the ice tray. The method according to any one of claims 2 to 5, And a predetermined number of ice cubes are formed in the ice tray of the ice tray by partition ribs, and a stress relief part having a corrugated shape is formed at the corner of each ice cube. The method of claim 6, The stress relief unit is an ice maker of the refrigerator formed on the side edge portion and the bottom edge of each ice cube.

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