KR20000007867A - Method of controlling ice motor of refrigerator - Google Patents

Abstract

PURPOSE: A method of controlling an ice motor of a refrigerator is provided to improve the degree of use satisfaction by making easy the taking out of ice and the durability of the part by preventing the occurrence of a field claim. CONSTITUTION: A method comprises the steps of:judging if the ice manufacture process is completed after water supply process; judging if an ice taking out signal is input after performing ice separation process if the ice manufacture process is completed; judging if over load is produced after driving an ice motor if the taking out signal is input; judging if an ice taking out stoppage signal is produced after reverse rotating the ice motor for a certain time if the over load is produced; and returning to the first step after stopping the driving of the ice motor if the ice taking out stoppage signal is produced.

Description

How to control the ice motor of the refrigerator

The present invention relates to a method for controlling an ice motor of a refrigerator, and in particular, in an ice storage container of an ice maker, when the ice motor is stored in a state where ice is entangled with each other and the ice motor driving the ice feeder is overloaded, The present invention relates to a method for controlling an ice motor of a refrigerator that facilitates taking out ice by rotating the ice motor for a predetermined time to separate the ice.

Recently, as the dietary culture of Korea is gradually westernized, the ice consumption rate is greatly increasing. Also, as the tastes of consumers are gradually diversified, large-capacity compound refrigerators equipped with various convenience facilities are rapidly spreading to general households. have. The most representative example of such a convenience facility is a dispenser that allows water or ice to be easily taken out of the refrigerator.

In general, an internal structure of a refrigerator having a dispenser capable of selectively extracting water or ice includes a water supply unit 10 for supplying water introduced from the outside into the freezer compartment and the refrigerating compartment, as shown in FIG. 1; A water tank 20 for storing water supplied from the water supply unit 10; A water supply pipe 31 for transferring water supplied from the water tank 20 to a refrigerating chamber; The dispenser 40 is configured to selectively take out the water transferred through the water supply pipe 31 and the ice supplied from the water supply unit 10.

The water supply unit 10 and the water supply valve 11 for supplying or blocking the water flowing through the external water pipe; A filter 12 for purifying water supplied through the water supply valve 11; It consists of a water supply control valve 13 for distributing the purified water through the filter 12 toward the freezer compartment and the refrigerating compartment.

The ice making unit 30 includes an ice making container 33 for receiving the water transferred through the water supply pipe 31; An ice maker 32 for ice-making water contained in the ice maker 33; It consists of an ice storage container 34 for receiving and storing the ice iced by the ice maker 32 from the ice making container 33, the ice storage container 34 is connected to the dispenser (40). .

The dispenser 40 is provided with a front panel 42 of the dispenser 40 at one side of the refrigerating compartment door, and the front panel 42 has a water selection button 45 and an ice selection button for selecting a desired item. 46 is formed, and an outlet 43 for discharging the item is formed inside the front panel 42, and the outlet 43 is pressurized and operated so that the dispenser 40 can be operated. The lever 44 protrudes.

FIG. 2 is an enlarged cross-sectional view illustrating the internal structure of the ice making unit of FIG. 1, wherein an ice making container 33 receives iced water and performs an ice making stroke with cold inside the freezing chamber; A heater (not shown) mounted on a bottom surface of the ice making container 33 to separate the ice made in the ice making container 33 from the ice making container 33 by heat; An ejector rotatably installed on an upper side of the ice making container 33 to take out the ice separated from the ice making container 33 by the heater; An ice storage container 34 which receives the ice taken out by the rotation of the take-out container from the lower side of the ice making container 33 and stores a predetermined amount; It is composed of means for transferring the ice contained in the ice storage container 34 to the dispenser (40).

In addition, as the conveying means, an ice feeder 36 is provided inside the ice storage container 33, and the ice transporter 36 is a motor 37 provided outside the ice storage container 33. It is connected to the shaft 38 so that it can be operated by the driving force of the), the front end of the ice transporter 36 is provided with a rotary distributor 39 for dividing into the shape of the ice type desired by the user.

In addition, the ice storage container 33 is connected to the ice inlet 35 on the upper side thereof with the cup insertion opening 47 in the dispenser 40 on the freezer door side with the ice transferred by the ice transporter 36. A blowout port 43 is formed to communicate with each other, and a blowout lever 44 is installed at a front portion thereof so as to receive the ice of the ice maker 32 or the water of the water tank 20 in a cup by pressing the user. It is.

The refrigerator configured as described above is operated to allow the user to directly receive iced or water iced in a cup while performing the refrigerating and freezing functions according to the principle of the refrigeration cycle like a conventional refrigerator. As follows.

First, a water supply stroke is made into the refrigerator main body through a water supply pipe from an external water supply source, and the water supplied in this way is selectively introduced into the water supply control valve 13 from the filter 12, and the water supply control valve 13 The water introduced into the water is selectively supplied to the ice making unit 30 through the upper water supply pipe 31, or water supplied to the water tank 20 through the lower water supply pipe 41, and in the ice making unit 30. The ice maker 32 ices the water supply, and a predetermined amount of water is stored in the water tank 20. In this state, if the user wants water or ice, the water selection button 45 or the ice selection button 46 provided on the panel 42 of the dispenser 40 is pressed to selectively water or ice through the dispenser 40. Ice will be received in the cup 38 to drink.

Meanwhile, after the water supply stroke for the ice maker 32 is finished, as shown in FIG. 3, when the ice making stroke is completed by determining whether the ice making stroke is completed, the ice in the ice maker 33 of the ice maker 32 is The ice taken out by the rotation of the take-out container is collected in the ice storage container 34 at the lower side of the ice making container 33 and stored in a predetermined amount.

The ice collected in the ice storage container 34 at the lower side of the ice making container 33 is transferred to the dispenser 40 by pressing the ice selection button 46 provided at the dispenser 40.

That is, when the user presses the ice selection button 46 of the dispenser 40 in a state where a certain amount of ice is stored in the ice storage container 34, the ice motor 37 is driven while being rotated forward according to its operation signal. , The driving force thereof is the ice feeder 36 connected to the ice motor 37 and the shaft 38 is rotated forward to transfer the ice in the ice storage container 34 to the ice inlet 35 side, the ice inlet 35 Ice is transferred to the dispenser 40 side.

Then, it is determined whether the ice motor 37 has an overload greater than a predetermined force, and in the case of an overload, the ice motor 47 is immediately turned off. After a predetermined time (t) has elapsed by the transfer of ice by), the ice motor 37 is turned off and the water supply and ice making operations are performed again.

As described above, in the prior art, when ice is stored in a state in which ice is entangled with each other, and an overload is applied to the ice motor driving the ice feeder, ice is not taken out and field cracks are generated. There was a problem that this was lowered, followed by inconvenience in use.

Therefore, the present invention was devised to solve the above-mentioned conventional problems, and when the ice motor is overloaded, the ice motor is rotated in reverse for a predetermined time to separate the ice, thereby making it easier to take out the ice. The purpose is to provide a method.

1 is a schematic internal structural diagram of a refrigerator provided with a dispenser for water / ice selective extraction;

Figure 2 is an enlarged cross-sectional view showing the internal structure of the ice making unit of FIG.

3 is an operation flowchart of the ice motor control method according to the prior art.

4 is an operation flowchart of the ice motor control method according to the present invention.

*** Description of the symbols for the main parts of the drawings ***

10: water supply unit 11: water supply valve

12 filter 13 water supply control valve

20: water tank 31, 41: water supply pipe

32: ice maker 33: ice maker

34: ice container 35: ice inlet

36: ice transfer machine 37: ice motor

38 axis 39 rotation distributor

40: dispenser 42: front panel

43: outlet 44: ejection lever

45: water selection button 46: ice selection button

47: cup insertion hole 48: cup

Ice motor control method of the refrigerator according to the present invention for achieving the above object comprises a first step of determining whether the ice making stroke is completed after the water supply stroke; A second step of determining whether an ice extraction signal is input after performing an ice-breaking operation when the determination result of the first step is completed; A third step of determining whether an overload occurs after driving the ice motor when the extraction signal is inputted as a result of the determination of the second step; A fourth step of determining whether an ice extraction stop signal is generated after the ice motor is rotated in reverse for a predetermined time when the overload occurs as a result of the determination in the third step; When the ejection stop signal is generated as a result of the determination in the fourth step, the driving of the ice motor is stopped, and then the fifth step is returned to the first step.

The fourth step is characterized in that it comprises the step of separating the ice by repeatedly rotating the ice motor to the left for a predetermined time, and then repeatedly rotated forward to the right for a predetermined time when the overload occurs.

Hereinafter, an operation process of an embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

4 is an operation flowchart of the present invention, the configuration of an embodiment for applying the present invention as shown therein is configured in the same manner as shown in FIG.

That is, after finishing the water supply administration, it is determined whether the ice making administration is completed, and if the ice making administration is completed as a result of the determination, the ice making administration is performed.

Here, when the user presses the ice selection button 46 of the dispenser 40 to generate an ice extraction signal, the ice motor 37 is rotated forward according to the ice extraction signal, and the driving force thereof is the ice motor ( The ice feeder 36 connected to the shaft 38 and the shaft 38 is rotated forward to transfer the ice in the ice storage container 34 to the ice inlet 35, thereby transferring the ice through the ice inlet 35. 40).

At this time, if it is determined whether an overload greater than a predetermined force is applied to the ice motor 37, and if an overload occurs, the ice motor 37 is rotated to the left for a predetermined time and then rotated to the right again for a predetermined time. Repeat several times to separate the ice and take out the ice.

Thereafter, it is determined whether the ice take-off stop signal has occurred, and if the take-off stop signal has occurred, the driving of the ice motor 37 is stopped, the ice motor 37 is turned off, and the water supply operation is repeated again. It is supposed to perform.

As described in detail above, in the present invention, when the ice motor is overloaded, the ice motor is rotated in reverse for a predetermined time to separate the ice, thereby easily extracting the ice to improve the satisfaction of the field crane, There is an effect of preventing the occurrence of the parts to improve the durability.

Claims (2)

A first step of determining whether the ice making stroke is completed after the water supply stroke is finished; A second step of determining whether an ice extraction signal is input after performing an ice-breaking operation when the determination result of the first step is completed; A third step of determining whether an overload occurs after driving the ice motor when the extraction signal is inputted as a result of the determination of the second step; A fourth step of determining whether an ice extraction stop signal is generated after the ice motor is rotated in reverse for a predetermined time when the overload occurs as a result of the determination in the third step; And a fifth step of returning to the first step after stopping the driving of the ice motor when the ejection stop signal is generated as a result of the determination in the fourth step. The method of claim 1, wherein the fourth step includes the step of separating the ice by repeatedly rotating the ice motor to the left for a predetermined time and then rotating the ice motor to the right for a predetermined time if an overload occurs. Ice motor control method of the refrigerator characterized in that.