KR19980023149A - How to control ice making to prevent water tip clogging - Google Patents

Abstract

The present invention proposes an ice making control technology for preventing water tip clogging to prevent freezing of the water tip installed at the tip of the water supply hose of the automatic ice maker for a refrigerator.

The water supply motor 15 and the water supply hose 16 for supplying the water of the bucket 13 installed in the refrigerating compartment to the ice making vessel 11 in the freezer compartment with the ice making sensor 24 and the water supply hose A water supply tip 18 mounted at the freezing chamber side tip of the 16, a heater 19 installed at the tip of the water supply tip to prevent water film ice from being formed at the opening of the water supply tip 18, and the heater The system control method by the microcomputer 20 in the automatic ice making system including the microcomputer 20 for controlling the energization to (19), the step of determining whether the deicing limit time (2.4 hours) has reached after the ice making start, and Determining whether the present temperature value of the ice tray 11 by the ice making sensor 24 reaches the reference temperature value (−12.5 ° C.) if the limit time is reached in the step;

In this step, if the detected temperature value by the ice-making sensor 24 is less than the reference temperature value, it is determined that the present ice making mode has failed, and if the detected temperature value is more than the reference temperature value, the execution of the ice-making mode and the execution of this ice mode simultaneously. Supplying an operating current to the heater 19 for a period of time, and executing the water supply mode and the water supply confirmation mode when the ebbing and heater energization modes are completed, and ending the deicing of the session. An ice making control method for

Description

How to control ice making to prevent water tip clogging

The present invention relates to a control method of an automatic ice maker installed in a freezer compartment of a refrigerator, and in particular, after installing a heater on a water supply tip to prevent clogging of a water hose tip that may be generated in a water supply system of an ice maker. The present invention relates to an ice making control method for preventing a water tip clogging having a program that can effectively control the energization.

In recent years, large refrigerator products have been equipped with automatic ice makers in response to demand from consumers and increased demand.

The automatic ice maker includes an ice making control device including a water tank, an ice making motor, and an ice making container in an refrigerator of a refrigerator, and an ice storage container for storing each ice produced in the ice making container.

The ice making system allows a certain amount of water to be supplied from the water tank to the ice tray each time through a water pump, thus allowing the ice iced in the ice tray to accumulate in the ice container.

Such an ice making system organically combines a sensor or timer for determining the water supply operation time of the feed water pump, a temperature sensor for detecting whether the ice making process is completed, and an ice making motor for rotating the ice tray to execute the ice making operation. It is made up.

Accordingly, when it is sensed that the ice making is completed by the temperature sensor, the ice making bowl is rotated by the reduction gear connected to the ice making motor and reaches a predetermined angle, which is twisted by a bracket to decompose the ice finished and falls into the storage container.

After the ice tray is rotated in one direction, after a certain time, it is rotated again in the opposite direction to return to its original position to perform the subsequent ice making operation.

The structure of the ice maker is divided into the front and rear cases, the moving motor, the gear cam, the gear plate, the horizontal and the ice switch, the auxiliary plate, and the ice tray installed on the gear plate.

We look at the ice making process in these ice makers.

First, when the ice maker is powered on, an initial control operation is performed to keep the ice tray horizontal.

This initial control is achieved by a horizontal switch that rotates the ice motor forward or reverse.

In addition, immediately after the power is turned on, water is not immediately supplied to the ice making vessel, and first, the operation of ice-making on the current ice making vessel by the ice making up to now is performed, and then the water supply step is executed.

This is to prevent water supply failure that may be caused by water supply in the ice making state.

After the initial control, the ice making completion control operation is executed.

This is determined after completion of water supply (2.4 hours: 144 minutes) when the temperature is below the reference temperature (-12.5 ℃) by the I (defrosting) sensor installed at the bottom of the ice making vessel is determined to be complete ice making.

As a result, an ice control operation occurs.

The ice control rotates the ice motor after the completion of ice making to rotate the ice bowl by the gear cam to induce the torsion of the case by the auxiliary plate so that the ice cubes separated from the ice tray are stored in the ice storage case installed directly below. .

After the ice is completed, the ice motor is rotated in reverse to adjust the horizontal state of the ice tray to the horizontal switch, and then it is determined whether or not it is full and then water is supplied.

In the above, whether or not the ice is detected by the ice-switching switch, if the on-contact signal is generated from the ice-switching switch, it is determined that it is not the ice-conditioning condition and executes the water supply control step for continuous ice-making.

If the ice switch is in the off state, it is determined as a high ice condition, and the water supply standby state and the ice making system are stopped.

If the amount of ice storage is insufficient after the completion of the ice, as described above, in order to execute the water supply control step, the operating power is supplied to the water supply motor for a predetermined time.

At this time, if water is continuously detected by the water supply sensor while supplying water, the water is supplied after 30 minutes.

If the current condition is the water detection condition by the water supply sensor, the water supply operation after the ice is confirmed by checking the water supply by turning on the test switch after stopping the abnormal state factor after stopping the ice making system.

When water is supplied to the ice making vessel during the ice making process, the water supply hose located inside the freezer compartment is easily frozen by a very low internal temperature.

Thus, a heater for preventing freezing is provided on the water supply hose.

1 shows a water supply system structure in an automatic ice maker for a refrigerator.

As referred to herein, in the refrigerating chamber 12 of the refrigerator, a bucket 13 to store water for ice making and a water dish 14 receiving water supplied from a bucket and maintaining a constant water level and the water dish ( A water feed motor 15 for pushing up the water of 14) to the ice making vessel side of the freezer compartment side is provided.

In addition, the freezing chamber 10 is provided with an ice making bowl 11 and a water supply hose 16 for supplying water to the ice making bowl 11, and the secondary water hose 16 has a water supply motor 15 side of the refrigerating compartment. Is being connected to.

The water supply hose 16 is equipped with a heater 17 for preventing the freezing of the hose.

Accordingly, when the operation of the automatic ice maker is started, the water supply motor 15 is driven so that the water on the water supply plate 14 is supplied to the ice making vessel 11 through the water supply hose 16.

In this ice making process, the heater 17 is continuously supplied with current, thereby preventing freezing of the water supply hose 16 by heat generated therein.

However, the water supply hose freezing prevention method by the conventional heater continuous energization method is unnecessary, there is a problem that will cause excessive power loss and high internal temperature rise.

As a countermeasure, a water supply hose heater energization control control method of an ice maker capable of solving an unnecessary power consumption problem in an automatic ice maker operating mode and minimizing a high temperature rise problem according to the present invention is provided by the present applicant. It is proposed in the hose energization control method.

This technology is characterized in that the water hose freeze prevention system of an automatic ice maker which mounts a hose anti-freezing heater on a water supply hose which delivers the water of the refrigerating chamber upwardly supplied by the water supply motor to the ice making vessel and supplies current thereto, Detecting a freezer compartment atmosphere temperature of the refrigerator detected by the sensor, comparing the temperature change cycle of the refrigerating compartment detected in the step to a reference value which is a set temperature, and allowing the temperature change cycle to rise past the reference value in the step; Blocking the current supplied to the heater from the time point at which the refrigeration chamber temperature cycle falls through the reference value to the operation of the refrigeration fan, and refrigeration from the time point at which the temperature change cycle falls below the reference value. The refrigerator temperature cycle cycles the reference value by turning off the fan. It is to include the step of supplying the current to the heater in the form of pulse train until the time to rise.

Accordingly, when controlling the energization of the heater mounted on the hose of the freezer compartment to prevent freezing of the water hose which may occur in the water supply system of the automatic ice maker installed in the freezer compartment of the large refrigerator, the temperature change of the freezer compartment is read and its characteristics By interlocking with the graph and controlling the water heater freeze protection heater in the form of pulse train, it is possible to solve the problem of unnecessary power consumption and high temperature increase due to the continuous operation of the heater based on the conventional method.

However, even if automatic de-icing is performed in this way, the water supply clogging at the tip of the feed hose is inevitable.

The reason is that the water supply hose is made of plastic with low thermal conductivity, but the tip of the water supply hose has a high thermal conductive metal material such as aluminum to prevent deformation of the hose outlet. Water blockage will occur.

An object of the present invention is an ice making control method for preventing water tip clogging to prevent water tip freezing caused by the water film ice is made by the water droplets remaining after the water is discharged from the tip of the water supply hose of the automatic ice making device To provide.

A water supply motor and a water supply hose for supplying water from a bucket installed in a refrigerating compartment to an ice making vessel in a freezer compartment equipped with an ice making sensor, a water supply tip mounted on a freezing chamber side end of the water supply hose, and the water supply tip In the automatic deicing system including a heater installed at the tip of the water supply tip to prevent the formation of water film ice at the opening, and a microcomputer for controlling the energization of the heater, the system control method by the microcomputer, after the ice making start deicing Determining whether the limit time (2.4 hours) has been reached,

Determining whether the present temperature value of the ice making vessel by the ice making sensor reaches the reference temperature value (-12.5 ° C.) if the limit time is reached in the step;

In this step, if the detected temperature value by the ice making sensor is equal to or less than the reference temperature value, it is determined that the present ice making mode has failed, and when the detected temperature value is equal to or greater than the reference temperature value, the icing mode is executed simultaneously with the Supplying a working current to the heater,

When the execution of the ice and the heater energization mode is completed, the water supply mode and the water supply confirmation mode, and the step of ending the ice making of the session.

1 is a diagram illustrating the structure of a water supply system of an automatic ice maker for a refrigerator.

Figure 2 is a structural diagram of the clogging prevention device of the water supply tip for the present invention.

3 is a circuit block diagram of an ice making control system for implementing the present invention.

4 is a flowchart for explaining the present invention.

** Explanation of symbols on main parts of the drawing **

10 freezer 11: ice tray

12: refrigerator compartment 13: bucket

14: water supply plate 15: water supply motor

16: water supply hose 17: heater

18: water supply tip 19: heater

20: Micom 21: Ebbing Motor

22: ice maker driving unit 24: ice maker

31: water supply motor drive part 32, 35: relay

34: heater driving unit

Hereinafter, the present invention will be described based on the accompanying drawings.

Figure 2 shows the installation structure of the water supply tip water film prevention heater 19 which is a controlled device according to the present invention.

As shown here, the water supply tip 18 installed at the tip of the water supply hose 16 is typically made of aluminum, and the heater 19 is wound and mounted on the water supply tip 18 of the metal.

3 is a configuration diagram of a system control circuit of an automatic ice making apparatus for implementing the present invention.

Here, at the input terminal IN of the microcomputer 20, the change in temperature proportional resistance value detected by the ice making sensor 24 is converted into a voltage component by the reference resistor 26 and the Vcc voltage, thereby limiting the current limiting resistor 25. Connect to be applied via.

The ice maker 24 is a sensor installed on the ice tray 11 of the freezer compartment of the refrigerator.

The ice maker 24 is a sensor installed on the ice tray of the freezer compartment of the refrigerator.

The control output signals generated at the first and second output terminals OUT1 and OUT2 of the microcomputer 20 are connected to the feed water motor driver 31 and the heater driver 34, respectively.

The water supply motor driver 31 includes an inverter and a relay 32 to be driven by a B + voltage, and is configured by connecting an AC voltage to be supplied to the water supply motor 15 by a contact of the relay 32.

The heater driving unit 34 includes an inverter and a relay 35 to be driven by the B + voltage, and is configured by connecting an AC voltage to be supplied to the heater 19 by a contact of the relay 35.

The ice control signal output from the third output terminal OUT3 of the microcomputer 20 is connected to the ice maker driver 22 so as to be connected to the ice maker driver 22 so that the ice motor 21 is driven forward and reversely by the ice maker driver 22. .

An ice making control method of the present invention based on such an automatic ice making device and a system control hardware structure will be described in detail below with reference to FIG. 4.

First, the water of the bucket 13 installed in the refrigerating chamber 12 is automatically supplied to the ice making vessel 11 in the freezing chamber 10 to which the ice making sensor 24 is attached by the water supply motor 15 and the water supply hose 16. The ice making mode is started.

After that, the microcomputer 20 starts timing to check whether the preset ice making time limit (2.4 hours) has been reached.

Herein, when it is determined that the limit time is reached, the microcomputer 20 performs the step of executing the ice mode, and if it has not yet reached the set ice limit time, the microcomputer 20 of the ice tray 11 sensed by the ice making sensor 24 is performed. Read the current temperature value.

At this time, when looking at the temperature sensing process of the ice tray 11 of the freezing chamber 10 by the ice maker 24, the ice maker is installed under the ice tray, the change in its resistance value according to the temperature change is applied to the ice maker 24. Since the Vcc voltage dividing circuit is made together with the reference resistor 26 connected in series, the temperature conversion voltage value obtained here is transmitted to the microcomputer side through the current limiting resistor 25 so as to know the current temperature in the refrigerator.

Through this process, a determination is made as to whether the current ice making vessel temperature reaches the reference temperature value (-12.5 ° C.).

In this step, if the detected temperature value by the ice making sensor 24 is less than or equal to the reference temperature value, it is determined that the present ice making mode has failed and ends.

On the contrary, if the detected temperature value is equal to or higher than the reference temperature value, the icing mode is executed and at the same time, the step of supplying an operating current to the heater 19 during the execution period of the icing mode is performed.

That is, if the detected temperature value by the ice making sensor 24 is the ice satisfying temperature, the microcomputer 20 performs a forward mode on the ice maker driving unit 22 side for driving control of the ice motor 21 through its third output terminal OUT3. The icing operation is executed by sending out a sequential control signal consisting of the warping mode, the reverse mode, the forward mode, and the stop.

At the same time, the microcomputer 20 emits a heater control signal through its second output terminal OUT2 for the driving period into the heater 19 installed on the feed tip 18 at the same time.

Accordingly, since the relay 35 of the heater driver 34 is driven and the contact thereof is turned on, a driving current is supplied to the heater 19.

Therefore, in the automatic ice making mode, the ice film that can be made on the water supply tip 18 is melted immediately before the water supply mode to be executed after the ice operation, thus preventing the water supply failure that may be derived by clogging the water supply tip by remaining water droplets. It becomes the number.

On the other hand, when the ice mode is completed, the microcomputer stops the operation of the heater 19 and outputs a control signal for executing the water supply mode through the first output terminal OUT1 thereof.

As a result, the relay 32 in the water supply motor driving unit 31 is operated so that the contact point thereof is turned on, thereby driving the water supply motor 15.

After the completion of water supply and confirmation step, the next ice making is made through the same process as described above.

In the present invention as described above, in the automatic ice making apparatus installed in the refrigerator, a heater is attached to a metal water supply tip, and the heater is energized during the ice-making period immediately before the next water supply mode is executed. The water outlet of the tip of the water supply hose of the water due to the water droplets remaining after the water is made here, the unique effect that can prevent the water supply tip freezing generated.

Claims (1)

A water supply motor 15 and a water supply hose 16 for supplying water from the water tank 13 installed in the refrigerating compartment to the ice making vessel 11 in the freezer compartment with the ice making sensor 24 and the freezing of the water supply hose 16. The water supply tip 18 mounted to the measurement front end, the heater 19 provided in the water supply tip end part in order to prevent water film ice from forming in the opening of the said water supply tip 18, and the electricity supply to the said heater 19 In the control method of the automatic ice making system comprising a microcomputer 20 to control the, Determining whether an ice making time limit (2.4 hours) has been reached since the ice making start, Determining whether the present temperature value of the ice tray 11 by the ice making sensor 24 reaches a reference temperature value (−12.5 ° C.) if the limit time is reached in the above step; In this step, if the detected temperature value by the ice-making sensor 24 is less than the reference temperature value, it is determined that the present ice making mode has failed, and if the detected temperature value is more than the reference temperature value, the execution of the ice-making mode and the execution of the ice-making mode at the same time Supplying an operating current to the heater 19 for a period of time, And executing the water supply mode and the water supply confirmation mode when the execution of the ebbing and heater energization modes is completed, and ending the ice making of the session.