KR0182721B1 - Apparatus and method for controlling the water supply of automatic ice making machine - Google Patents

Abstract

The present invention relates to a water supply control apparatus and method for an automatic ice maker for a refrigerator, and an ice-making container provided in a freezer compartment, a storage tank provided in a refrigerator compartment, to receive water, and a water-supply motor pumping water from the storage tank to supply the ice-making vessel. In the automatic ice maker for a refrigerator having a water supply, the water supply motor driver 150 for controlling the driving of the water supply motor 24, and the magnitude of the input power voltage supplied to the water supply motor when the water supply motor 24 is driven. The input voltage sensing unit 160 and the detection result of the input voltage sensing unit 160 are input to calculate a driving time of the water supply motor 24 according to the magnitude of the input voltage, and according to the calculated driving time. The microcomputer 100 outputs a predetermined control signal to the water supply motor driver 160 to control the operation of the water supply motor. The water supply control method is based on the configuration of the water supply motor. Detecting a magnitude of an input voltage applied to the water supply motor, setting a water supply time according to the magnitude of the detected input voltage, and rotating the water supply motor forward for a set water supply time to perform water supply to an ice making container. Characterized in having a step.

Description

Water supply control device and method of automatic ice maker for refrigerator

The present invention relates to an automatic ice maker for a refrigerator, and more particularly, to control a driving time of a water supply motor according to a change in an input voltage, by supplying a certain amount of water to an ice making machine at all times to achieve a uniform ice making operation. The present invention relates to a water supply control apparatus and a method of an ice maker.

As shown in FIG. 1, a refrigerator having a general automatic ice maker includes a freezer compartment 3 and a refrigerating compartment 4 intersected by an intermediate partition 2 on the refrigerator body 1, and a freezer compartment 3 and a refrigerator compartment. (4) is opened and closed by the freezing chamber door 5 and the refrigerating chamber door 6, respectively. A cooler 7 is installed at the rear of the freezer compartment 3 to generate cold air, and a cooling fan 8 is installed above the cooler 7 so that the generated cool air is supplied to the freezer compartment 3 and the refrigerating compartment 4. Forced circulation In order to guide the supply of cold air, the front plate 9 and the rear plate 10 are installed in front of the cooling fan 8, and the cold plate discharge port is provided in the front plate 9 to guide the supply of cold air to the freezer compartment 3. (11) is formed, the refrigeration chamber duct 12 is installed in the back plate 10 to guide the supply of cold air to the refrigerating chamber (4).

On the other hand, the freezing chamber (3) is provided with an automatic ice maker (20) for making ice using cold air generated in the cooler (7). As shown in FIG. 1, the automatic ice maker stores water in a plurality of concave grooves 210g formed therein to make ice using ice of the freezing chamber 3 and an ice maker 21. It is provided with a storage container 22 for storing the ice cube made in 21). In the refrigerating chamber 4, a water storage tank 23 and a water supply motor 24 for supplying water to the ice making container 21 are installed, and water in the water storage tank 23 is transferred to the ice making container 21. A water supply hose 25 for delivery is disposed from the water storage tank 23 of the refrigerating compartment 4 over the upper part of the ice making container 21 of the freezing compartment 3. In the front of the ice-making container 21, when ice-making is completed, the drive part 26 which rotates the ice-making container 21 about 135 degrees, twists, and drops an ice cube to the ice-cream container 22 is installed.

The automatic ice maker configured as described above is repeatedly repeated ice making, ice-making and water supply operation by a control unit (not shown), wherein the water supply operation is first made in the ice making container 21 when the water supply condition is satisfied. When it is detected that the ice cubes are all iced into the ice storage container 22, the water supply motor 24 is driven to pump water from the water storage tank 23 to supply the ice making container 21 to perform the ice making operation. At this time, whether the water supply to the ice making container 21 is completed is determined by the driving time of the water supply motor 24. When the driving time of the water supply motor 24 reaches a predetermined time or more, the driving is turned off and the water supply operation is performed. Will be completed.

However, in the conventional water supply control method, when the input voltage applied to the water supply motor is changed, that is, when the input voltage is increased and the rotation speed of the water supply motor is increased, the quantity of water that is more suitable for the ice making container during the driving time of the water supply motor is set. When more water is supplied or the input voltage is lowered, the rotation speed of the water supply motor is reduced, so that less water than the predetermined standard water is supplied to the ice making container and the amount of ice cube generated during a certain time and its size There was an inconsistent problem.

Accordingly, the present invention has been made to solve this problem, the object of the present invention is to control the water supply of the automatic ice maker for refrigerators to maintain a constant amount of water supplied to the ice maker by changing the water supply time in accordance with the change of the input voltage. And to provide a method.

1 is a cross-sectional view showing the configuration of a typical automatic ice maker for a refrigerator.

2 is a schematic block diagram of an automatic ice maker for a refrigerator according to the present invention.

FIG. 3 is a detailed circuit diagram of the feedwater motor driver and the input voltage detector shown in FIG. 2.

4 is a flowchart illustrating a water supply control method of an automatic ice maker for a refrigerator according to the present invention.

5 is a table showing the relationship between the drive time of the feedwater motor to the sensed voltage value according to the present invention.

Explanation of symbols on the main parts of the drawings

20 ... automatic ice maker, 21 ...

22 ... storage container, 23 ... storage tank,

24 ... water supply motor, 25 ... water supply hose,

100 ... microcom, 110 ... power supply,

120 De-icing temperature detection unit, 130 Time counting unit,

140 ... Iving Motor Drive, 150 ... Water Supply Motor Drive,

160 ... Input voltage detector.

In order to achieve the above object, a water supply control apparatus for an automatic ice maker for a refrigerator according to the present invention is provided in an ice making container provided in a freezer compartment, a refrigeration chamber, a storage tank for fresh water, and pumps water from the storage tank to supply the ice maker. An automatic ice maker for a refrigerator having a water supply motor, the water supply motor driver controlling the driving of the water supply motor, and an input voltage sensing unit sensing a magnitude of an input power voltage supplied to the water supply motor when the water supply motor is driven. The driving time of the water supply motor is calculated according to the magnitude of the input voltage by receiving the detection result of the input voltage sensing unit, and a predetermined control signal is output to the water supply motor driver to control the driving of the water supply motor according to the calculated driving time. Characterized in that provided with a microcomputer.

In addition, the water supply control method of the automatic ice maker for refrigerators according to the present invention is provided in the ice-making container installed in the freezer compartment, the storage tank is provided in the refrigerating chamber to store water, and to supply the water stored in the water storage tank to the ice maker through a water supply hose. A water level sensing method of an automatic ice maker for a refrigerator having a water supply motor and an input voltage sensing unit for sensing an input voltage supplied to the water supply motor, the magnitude of the input voltage applied to the water supply motor when the water supply motor is driven. And setting a water supply time according to the magnitude of the sensed input voltage, and rotating the water supply motor forward during the set water supply time to perform water supply to the ice making container.

Hereinafter, the configuration and the effect according to the preferred embodiment of the present invention will be described in detail.

First, Figure 2 is a schematic block diagram of an automatic ice maker according to the present invention. Thus, the automatic ice maker of the present invention, as shown, the microcomputer 100 to control the ice-making, ice, and water supply operation of the automatic ice maker as a whole, the power supply unit 110 for supplying the driving power of the microcomputer 100 and In order to detect the completion of ice making by sensing the temperature of the ice making container, the ice making temperature detecting unit 120 inputting a predetermined detection signal to the microcomputer 100, and when ice making is completed, rotate the ice making container 21 at a predetermined angle. Ice-driving motor driving unit 140 for moving the ice cubes from the ice-making container 21 to the ice-making container 22, and supplying water to the ice-making container 21 from the water storage tank 23 provided in the refrigerating chamber 4 when the ice-making operation is completed. The water supply motor driver 150 for controlling the driving of the water supply motor 24 and the time counting unit 130 for counting the driving time of the water supply motor 24 and inputting the counted driving time to the microcomputer 100. And, of the input voltage supplied to the water supply motor 24 It is provided with an input voltage detection unit 160 for inputting a detection signal to the microcomputer 100 to detect the size to control the water supply time.

In this configuration, the water supply motor driver 150 and the input voltage detector 160 receive a base signal from one output terminal P1 of the microcomputer 100 as shown in the detailed circuit diagram of FIG. 3. A transistor Q4 to be driven; a transistor Q4 connected to an emitter terminal of the transistor Q2; a base signal applied thereto; a transistor Q4 connected on and off; and a resistor R6 connected to an emitter terminal; and a transistor Q4 and a collector; -Connected to the PNP transistor Q3 connected to the collector, the transistor Q2 driven by receiving the base signal from the one output terminal P2 of the microcomputer, and the base signal connected to the emitter terminal of the transistor Q2. A transistor Q6 to be turned off and a PNP transistor Q5 connected to the transistor Q6 and collector-collector connected thereto are provided.

The base terminal of the transistor Q3 is connected to the collector-collector connection terminal of the transistors Q5 and Q6 via a resistor R5, and the base terminal of the transistor Q5 is connected to a resistor R7. It is connected to the collector-collector connection terminal of the transistors Q3 and Q4. In addition, both ends of the feed water motors for pumping water stored in the water storage tank and supplying them to the ice making container are connected to the collector-collector connection ends of the transistors Q3, Q4; Q5 and Q6, respectively.

The microcomputer 100 receives the voltage signal applied to the emitter resistor R6 of the transistor Q4 through the one input terminal R3 to determine the magnitude of the voltage applied to the feed water motor 24. The water supply time is adjusted by varying the driving time of the water supply motor 24 according to the voltage size.

Such a water supply control method of the present invention will be described in detail with reference to FIGS. 4 and 5.

4 is a flowchart illustrating a water supply control method of an automatic ice maker according to the present invention. As shown in FIG. 10, in operation S10, when it is determined whether ice making is completed, the ice making motor is driven in a predetermined direction, and each ice formed in the ice making container is moved to the ice storage container provided under the ice making motor. At this time, when it is determined that the ice is completed, in step S12, a predetermined control signal is output through the one output terminal P1 of the microcomputer to rotate the water supply motor forward. At this time, the input terminal P3 is driven as the water supply motor is driven. ), The voltage sensing signals across the resistor R6 are input. Accordingly, the magnitude of the input voltage is determined, and in step S14, the driving time of the feedwater motor, that is, the feedwater time is set according to the determined magnitude of the input voltage. As shown in the table shown in FIG. 5, the driving time of the water supply motor is variablely set according to the magnitude of the input voltage. When the magnitude of the input voltage is small, the water supply motor is rotated at low speed, and thus the driving time is set longer. If the input voltage is large, the water supply motor rotates at high speed, so set the driving time short.

On the other hand, when the water supply time is set in step S14, the water supply motor is rotated forward in step S16 and the time counting unit counts the driving time of the motor. Therefore, the water from the water storage tank is supplied to the ice making vessel installed in the freezing chamber by the drive of the water supply motor. In step S18, the motor driving time counted by the time counting unit is compared with the water supply time set in the step S14. When the water supply motor is driven until the water supply time elapses, the flow proceeds to step S20 to supply the water supply motor. Will stop driving.

In addition, when the water supply operation is completed, in step S22, when the driving of the water supply motor is stopped, when a predetermined time elapses, for example, 1 second elapses, the flow proceeds to step S24, where the water remaining in the water supply hose is stored by reversely rotating the water supply motor. Will be reduced into the tank. In step S26, if it is determined that the motor is rotated for a predetermined time, for example, 4 seconds, and the residual water in the water supply hose is all reduced, the process proceeds to step S28 to turn off the drive of the water supply motor to complete the water supply operation.

As described above, by detecting the magnitude of the input voltage applied to the water supply motor by the water supply control apparatus and method of the automatic ice maker for refrigerators according to the present invention, by varying the water supply time according to the magnitude of the input voltage per unit time The water supply is kept constant so that the size and angle of the ice cubes are kept constant during the ice making operation, and accurate water supply operation is performed.

Claims (3)

In an automatic ice maker for a refrigerator having an ice making container provided in a freezing compartment, a water storage tank provided in the refrigerator compartment to receive water, and a water supply motor for pumping water from the water storage tank and supplying the water to the ice making container, A water supply motor driver 150 for controlling driving of the water supply motor 24; The input voltage detector 160 detects the magnitude of the input power voltage supplied to the feedwater motor when the feedwater motor 24 is driven, and receives the detection result of the input voltage detector 160 to the magnitude of the input voltage. Correspondingly, the microcomputer 100 for calculating the driving time of the water supply motor 24 and outputting a predetermined control signal to the water supply motor driver 160 to control the driving of the water supply motor according to the calculated driving time. Water supply control device for an automatic ice maker for a refrigerator. Defrosting vessel installed in the freezer compartment, a storage tank for storing water in the refrigerating chamber, a water supply motor for supplying the water stored in the water storage tank to the ice making vessel through a water supply hose, and detecting the input voltage supplied to the water supply motor A water level sensing method of an automatic ice maker for a refrigerator having an input voltage sensing unit, the method comprising: detecting a magnitude of an input voltage applied to the feedwater motor when the feedwater motor is driven; And setting a water supply motor to rotate the water supply motor forward for a set water supply time. The water supply motor according to claim 2, wherein the water supply motor is stopped when the water supply time elapses, the operation is waited for a predetermined time, and when the waiting time elapses, the water supply motor is rotated in reverse for a predetermined time to store residual water in the water supply hose. Driving control method of the automatic ice maker for a refrigerator, characterized in that it further comprises the step of draining to the tank.