KR100266593B1 - Method for controlling separation of ice in icemaker for complex refrigerator - Google Patents

Abstract

PURPOSE: A method for controlling the separation of ice in an icemaker is provided to prevent an overload on a motor by preventing the sticking of ice in an ice container, to smoothly and accurately supply ice in the shape desired by a user, and to enhance the performance and reliability of an icemaker by reducing vibration and noise. CONSTITUTION: A method for controlling the separation of ice in an icemaker comprises the steps of setting up a reference rotational torque value of a motor in a microcomputer, comparing the reference rotational torque value of the microcomputer to a rotational torque value of the driving motor, reducing the rotational speed of the motor and increasing the rotational torque if the compared value reaches the reference value, deciding the elapse of a predetermined time while the motor is driven, and turning off the motor after the predetermined time is elapsed.

Description

Ice Separation Control Method of Combined Refrigerator Ice Maker

The present invention relates to an ice maker for making ice by receiving water supplied into a refrigerator main body, and in particular, an ice separation control of an ice maker for a multiple refrigerator that controls the ice stored in a state in which the ice is entangled in the storage container of the ice maker. It is about a method.

In general, unlike the upright refrigerator having a freezer compartment and a refrigerating compartment up and down, the combined refrigerator is a large-capacity refrigerator having a complex performance of various functions in which the freezer compartment and the refrigerating compartment are arranged left and right. In addition to the basic configuration of the freezer compartment 110 for storing food and the freezer compartment 120 for storing food as shown in FIG. 1, the composite refrigerator can receive ice or water in a cup by pressing a user's selection button. It also includes a dispense function. Various functions are provided inside the main body 100 of the composite refrigerator for this function, and the inside of the refrigerator main body 100 may be connected to an external water source and a pipe to filter the water supplied through the pipe. The filter unit 1, the water supply valve 2 for selectively blocking and opening the water supply passage of the water purified by the filtering unit 1, and the water supplied through the pipe from the water supply valve (2) The ice maker 3 for ice making, the water tank 4 for storing a predetermined amount of water supplied through the pipe from the water supply valve 2, and the pipe from the ice or water tank 4 made in the ice maker 3 Dispensing unit 5 is provided to drink the water supplied through the cup selectively by pressing a button of the user.

The ice maker 3 receives the water supplied as shown in FIG. 2 and performs an ice making stroke with cold inside the freezer compartment. The ice maker 3 uses ice produced by the ice maker 3A as heat. A heater (not shown) mounted on the bottom surface of the ice maker 3A for separating from 3A, and the ice maker 3A for taking out the ice separated from the ice maker 3A by the heater. An ejector rotatably installed on an upper side of the storage container, a storage container 3C for receiving a portion of ice taken out by the rotation of the ejector from the lower side of the ice making container 3A, and storing a predetermined amount in the storage container 3C; It is comprised by the means for conveying the contained ice to the said dispensing part 5 side. Also, as the transfer means, a transfer machine 3E is provided inside the storage container 3C, and the transfer machine 3E is driven by the driving force of the motor 3F provided on the outside of the storage container 3C. It is connected to the shaft (3G) so that it can be operated, the front end portion of the conveyor (3E) is provided with a rotary distributor (3H) and grinder (3I) for dividing into a shape for each ice type desired by the user. In addition, the ice container 3C is formed in the storage container 3C so that the ice transferred by the feeder 3E can be introduced into the dispensing unit 5 on the freezing chamber door 110A side. The part 5 is formed with a cup inserting opening 5A and an ejecting opening 5B at the upper side thereof so as to be connected to the ice feeding opening 3D, and the front part of the ice maker 3 is pressed by a user. The push button (5D) is provided to drink the ice or water of the water tank 4 in the cup.

The composite refrigerator configured as described above is operated such that a user can directly receive ice or water frozen in a cup while performing a refrigerating and freezing function according to the principle of a refrigeration cycle like a conventional refrigerator. Same as First, the water supply stroke is made into the refrigerator main body 100 through a pipe from an external water supply source. The water supplied in this way is purified through the filtering unit 1 and flows into the water supply valve 2 through the pipe, and the water introduced into the water supply valve 2 is selectively directed to the ice maker 3 through the upper side pipe. The water is supplied to the water tank 4 through the lower pipe or the lower side pipe, the ice maker 3 ices the water supply, and the water tank 4 stores a predetermined amount of water. In this state, the user selects a plurality of buttons provided on the panel of the dispensing unit 5. If ice is desired, the ice selection button is pressed, and if water is desired, the water selection button is pressed. Through the optional ice or water in the cup will be able to drink.

On the other hand, Figure 3 is a flow chart showing the operation state of the dispensing unit according to the conventional ice selection, as shown in the ice making operation by the ice maker 3, as shown therein, in the ice maker 3A of the ice maker 3 The ice is taken out by the rotation of the take-out container (not shown), and the extracted ice is collected in the lower storage container 3C of the ice making container 3A and stored in a predetermined amount. In addition, the ice-making container 3A is repeatedly formed with a water supply stroke, and ice is collected in the storage container 3C by pressing the ice selection button provided in the dispensing unit 5. It is conveyed to (5) side. That is, when the user presses the ice selection button of the dispense unit 5 while a certain amount of ice is stored in the storage container 3C, the motor 3F is driven for a predetermined time according to the operation signal thereof, and the driving force thereof is By rotating the feeder 3E connected to the motor 3F and the shaft 3G, the ice in the storage container 3C is transferred to the ice inlet 3D. In addition, the ice transferred to the ice inlet (3D) side is divided by the type of ice (angle ice and crushed ice) by the rotary distributor 3H to be distributed through the grinder 3I. After the ice transfer by the feeder 3E is completed, the motor 3F is turned off again to end the operation of the dispense unit by ice selection.

However, such a conventional refrigerator may not overload the motor, which is the driving source of the conveyor which transfers the ice in the storage container to the dispensing part when the ice stored in the storage container is entangled with each other through the ice making stroke, and severe vibration And there was a problem that noise occurs. In addition, when the motor is damaged by the overload as described above, the dispensing function by pressing the user's ice selection button is lost, causing inconvenience to the user as well as the reliability of the device. And when the user wants the piece of ice, there was a problem that the supply of the desired ice is not made smoothly, such as lumped ice is supplied. Therefore, the present invention is to ensure that even if the ice in the storage container is tangled with each other, the ice type supply to the dispensing portion by pressing the ice selection button of the user is made more accurately and smoothly.

1 is a perspective view showing the configuration of a dispensing function related device of a general refrigerator.

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

3 is a T-S diagram of the ice maker motor of FIG.

4 is a flowchart sequentially showing a conventional ice-making process.

5 is a T-S diagram of an ice maker motor according to the present invention.

5 is a flowchart sequentially illustrating a ribbing process according to the present invention.

<Explanation of symbols for main parts of drawing>

1: filtering part 2: water supply valve

3: ice maker 3A: ice maker

3C: Storage Container 3D: Ice Inlet

3E: Transporter 3F: Motor

3H: Rotary distributor 3I: Grinder

4: water tank 5: dispense unit

5A: Cup insertion slot 5B: Outlet

5C: Cup 5D: Pushbutton

6: filler portion 100: refrigerator body

110: freezer 120: cold storage room

In order to achieve the object of the present invention, the water supplied to the ice making vessel through the ice making stroke is iced, the ice in the ice making vessel is taken out and stored in the storage container in a predetermined amount by pressing the ice selection button provided in the dispensing motor. Operating ice to transfer ice in the storage container to the dispensing unit by rotating a feeder connected to the shaft by the motor, the first process of setting a reference torque reference value of the motor to the microcomputer; A second step of comparing and determining the reference value of the microcomputer and the rotation torque value of the driving motor; A third step of reducing the rotation speed of the motor and increasing the rotation torque when the comparison value calculated by the second step reaches a reference value; A fourth step of determining whether the driving time of the motor driven by the speed and the rotational torque has elapsed in the micom; When the time elapses, there is provided a method for controlling ice separation of an ice maker for a multiple refrigerator, comprising a fifth process of turning off the motor. Hereinafter, the method of the present invention will be described in more detail with reference to the accompanying drawings.

4 is a flowchart illustrating a conventional ice-making process in sequence, FIG. 5 is a T-S diagram of a motor of an ice maker according to the present invention, and FIG. 6 is a flowchart sequentially showing the ice-making process according to the present invention. In the combined refrigerator, water is supplied to the ice maker 3A of the ice maker 3 as usual, and the supplied water is iced by cold air circulating inside the freezer compartment. After the ice in the ice making container 3A is separated from the ice making container 3A by a heater, the ice is taken out by the rotation of the take-out container installed on the upper side of the ice making container 3A. A certain amount is stored in the storage container 3C provided on the lower side of the container 3A. In this state, when the user presses the ice selection button provided in the dispensing unit 5 to use ice, an operation signal command is given to the motor 3F by pressing it, and the driving force of the motor 3F is driven. It is transferred to the feeder 3E inside the storage container 3C connected by 3F and the shaft 3G. Accordingly, the conveyor 3E transfers the ice in the storage container 3C to the ice inlet 3D, and the ice transferred to the ice inlet 3D is dispensed through the ice inlet 3D. 5) is supplied.

In the combined refrigerator, the present invention is connected to the feeder 3E and the shaft 3G in the storage container 3C to convert the reference value of the rotation torque of the motor 3F to rotate the feeder 3E. -COM). In addition, when the rotational torque value of the motor 3F reaches the reference value set in the microcomputer, the rotational speed of the motor 3F is reduced and the rotational torque can be increased, and the rotational speed and the rotational torque are driven for a predetermined time. Set the time on the micom as possible. The motor 3F is automatically turned off when the time set in the microcomputer elapses. First, as shown in FIG. 6, a predetermined amount of ice is stored in the storage container 3C through an ice making stroke. When the user presses the ice selection button of the dispensing unit 5 to use ice, the motor 3F is turned on to move the feeder 3E connected to the motor 3F and the shaft 3G. By the rotation thereof, the ice inside the storage container 3C is transferred to the dispensing unit 5 side through the ice inlet 3D via the rotary distributor 3H and the crusher 3I, thereby dispensing the dispensing unit 5. It is to supply the ice into the cup (5C) seated inside the cup insertion opening (5A) of the), its operation is the same as the conventional. However, when the user does not press the ice selection button of the dispensing unit 5 for a long time, that is, without leaving the ice for a long time or frequently opening or closing the freezer door, the ice in the storage container 3C is entangled with each other. Is generated. Even in this state, when the user presses the ice selection button of the dispensing unit 5, the motor 3F is turned on and the feeder 3E inside the storage container 3C connected to the motor 3F and the shaft 3G. In this case, the microcomputer compares the rotation torque value of the motor 3F being driven with a reference value preset in the microcomputer. When the comparison value calculated by the comparison judgment is less than or equal to the reference value set in the micom, the motor 3F continues to drive until the reference value of the micom is reached. The motion control signal is sent to reduce the rotation speed of 3F) and increase the rotation torque. The motor 3F rotates the feeder 3E inside the storage container 3C connected to the motor 3F and the shaft 3G for a predetermined time by the rotation speed and the rotation torque, and the feeder ( The ice of the storage containers 3C entangled with each other by the operation of 3E) is separated from each other, and when the time set in the microcomputer elapses, the motor 3F is automatically turned off to terminate the work.

As such, the present invention can solve the ice entanglement in the storage container caused by neglect of the use of ice for a long time and frequent opening and closing of the freezer door by reducing the speed of the motor and increasing the torque. In addition to preventing overload in advance, the dispensing unit has an effect of supplying the desired ice more accurately and smoothly. In addition, less vibration and noise has the effect of further increasing the performance and reliability of the device.

Claims (1)

Water supplied to the ice making vessel is iced through the ice making stroke, and the ice in the ice making vessel is taken out and stored in the storage container for a predetermined amount to operate the motor by pressing an ice selection button provided in the dispensing unit and connected to the motor and the shaft. A first step of setting the rotation torque reference value of the motor in the microcomputer to transfer the ice in the storage container to the dispensing unit by the rotation of the conveyor; A second step of comparing and determining the reference value of the microcomputer and the rotation torque value of the driving motor; A third step of reducing the rotation speed of the motor and increasing the rotation torque when the comparison value calculated by the second step reaches a reference value; A fourth step of determining whether the driving time of the motor driven by the speed and the rotational torque has elapsed in the micom; The ice separation control method of the icemaker for a multiple refrigerator, characterized in that the fifth step of turning off the motor when the time elapses.

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