KR20000010109A - Water supply control device of ice-making machine in refrigerator and method thereof - Google Patents

Abstract

PURPOSE: A water supply control device of an ice-making machine in a refrigerator is provided to prevent the manufactured ice from congealing or getting smaller of its size by always supplying the water for making ice of a set amount without regard to the change of water pressure. CONSTITUTION: The water supply control device of an ice-making machine in a refrigerator contains:an operating panel unit(210) having a lighting lamp; a flow sensor(220) for outputting the spherical pulse by sensing the water supply quantity of the ice-making water fed from the outer water supply point; a valve apparatus(230) for controlling the water supply quantity of the ice-making water provided to a tray by installing itself on a water supply hose connected to the outer water supply point; a valve apparatus driving unit(240) for driving the valve apparatus(230); a refrigerator control unit(250) for controlling the valve apparatus driving unit(240); and a timer(280) for calculating the water supply time of the ice-making water provided to the outer water supply point under the control of the refrigerator control unit(250).

Description

Water supply controller and method for refrigerator ice maker

The present invention relates to a water supply control device and a method of the refrigerator ice maker, and in particular, a water supply control device of the refrigerator ice maker that allows water to be supplied to the tray by the set amount based on the pulse frequency of the flow sensor. And to a method thereof.

In general, ice makers in refrigerators can be easily produced without the user's troublesome operation, and thus are indispensably adopted in refrigerators. In recent years, automatic ice makers have been employed in refrigerators, and a typical example thereof is shown in FIG. 1.

1 is a longitudinal cross-sectional view of a refrigerator equipped with a conventional automatic ice maker, and includes a freezer compartment 3 and a refrigerating compartment 4 intersected by an intermediate partition 2 in the refrigerator body 1, and include a freezer compartment 3 and a refrigerating 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, in the freezing chamber 3 is provided with an automatic ice maker 20 for making ice by using the cold air generated in the cooler (7). As shown in FIG. 1, the conventional automatic ice maker 20 stores water in a plurality of concave grooves 21 ′ formed therein to make ice by using cold air of the freezing chamber 3. And a storage container 22 for storing the ice cubes formed in the ice making container 21. In addition, the refrigerating chamber (4) is provided with a water storage tank (23) and a water supply pump (25) for supplying water to the ice making container (21), and the water in the water storage tank (23) 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 25. 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 operated ice maker 20 is a water supply and ice making operation, and the ice operation is automatically performed by the refrigerator control unit (not shown).

However, the automatic ice maker of such a conventional refrigerator has a problem that the contents of the refrigerator for storing food are reduced as the storage tank 23 and the water supply pump 24 are provided in the refrigerator.

In view of this, a refrigerator ice maker which generates ice by receiving ice ice water from an external water source such as tap water is proposed, and the ice maker operation is automatically performed by the refrigerator controller. More specifically, the refrigerator control unit opens the valve installed in the water supply hose connected to the external water source, supplies the ice making water to the tray of the ice maker, and then checks the ice making state. It is separated and loaded into the ice making container.

In the ice maker of such a refrigerator, the refrigerator controller controls an operation of supplying an appropriate amount of ice making water to a tray. An embodiment of the related art is illustrated in FIG. 2A.

2A is a configuration diagram of a water supply control apparatus for a refrigerator ice maker according to an exemplary embodiment, in which a user displays a plurality of function keys for selecting an operation function of a refrigerator including an automatic ice making function and a selection state of a corresponding function key; The operation panel part 31 provided with a lighting lamp, the dip switch 32 for manually setting the water supply amount of the ice making water supplied to the tray of the ice maker, and the water supply hose connected to the external water supply source are supplied to the tray. The valve device 33 for adjusting the amount of ice-making water to be supplied, the valve device driver 34 for driving the valve device 33, the valves according to signals from the operation panel part 31 and the dip switch 32 It is comprised by the refrigerator control part 35 which controls the apparatus drive part 34 and controls the water supply operation of the ice-making water supplied to a tray. In the water supply control apparatus of the refrigerator ice maker according to the conventional embodiment as described above, the user must set the water supply time through the dip switch 32 in advance. That is, as illustrated in FIG. 2B, the water supply time of the ice making water supplied to the tray is set by individually turning on or off the first to third switches SW1 to SW3, and the refrigerator control unit 35 has a dip switch 32. ), The valve device driver 34 is controlled by recognizing the water supply time set according to the on / off state of the first to third switches SW1 to SW3. For example, when the user 'turns on' the first switch SW1 and turns off the second and third switches SW2 and SW3 to set the water supply time to “5 seconds,” the refrigerator control unit 35. Recognizes the water supply time set according to the on / off signals respectively input from the first to third switches (SW1 to SW3). When the user selects the automatic de-icing function through the operation panel 31 in the state in which the setting operation for the water supply time is completed as described above, the refrigerator control unit 35 controls the valve driving device 34 to operate the valve device 33. After opening the water supply operation for supplying the ice making water to the tray, and then the water supply time set by the dip switch 32 elapses, the valve device 33 is closed to stop the water supply operation of the ice making water.

However, the water supply control apparatus of the refrigerator ice maker according to the conventional embodiment does not consider the water pressure of the ice making water supplied from the external water source because the user manually set the water supply time corresponding to the water supply amount by operating the dip switch. Since only the water supply time is set, there was a problem in that the water cannot be supplied with the amount of ice making water in the tray when the hydraulic pressure is changed.

In consideration of this, another conventional embodiment of controlling a water supply operation by sensing a water supply amount through a flow sensor has been proposed as shown in FIG. 3A. 3A is a configuration diagram of a water supply control apparatus for a refrigerator according to another embodiment of the present invention, in which a user turns on a plurality of function keys for selecting an operation function of a refrigerator including an automatic ice making function and a selection state of a corresponding function key; Supply amount of the ice-making water supplied to the tray installed in the operation panel unit 110 having a lamp, a flow sensor 120 for detecting the water supply of the ice-making water supplied from the external water supply source, and a water supply hose connected to the external water supply source The valve device driver 140 for controlling the valve device 130, the valve device driver 140 for driving the valve device 130, and the signal from the operation panel 110 and the flow sensor 120. Is configured to control the refrigerator control unit 150 to control the water supply operation of the ice-making water supplied to the tray.

As shown in FIG. 3B, the flow sensor 120 is installed in the water supply hose at a predetermined distance from the rear of the valve device 130, and the impeller 160 rotates by the ice making water supplied from an external water supply source. A photocoupler 170 including a light emitting diode 180 installed at the front of the impeller 160 and a phototransistor 190 installed at the rear of the impeller and a transistor Tr1 connected to the phototransistor 190 are provided. When the flow sensor 120 is opened and the water supply operation is started, the flow sensor 120 rotates the impeller 160 by the ice making water supplied from an external water supply source, so that the light projected from the light emitting diodes 180 is impeller 160. The phototransistor 190 is driven in an on or off state by being blocked or passed by a wing of the blade. Accordingly, the photocoupler 170 outputs the spherical pulses to the refrigerator control unit 150 according to the amount of ice making water supplied. The refrigerator control unit 150 stores setting values corresponding to the cumulative values of the spherical pulses according to the cross-sectional area of the water supply hose, the inner volume of the tray and the water pressure, and the setting values are linear according to the water pressure as shown in FIG. It is decided based on increasing pulse frequency. That is, the refrigerator control unit 150 is a set value necessary for supplying the amount of ice-making water to the tray, for example, when the water pressure increases to reach the point A when the water supply of the amount of ice-making water to the tray pulses The set value is determined by accumulating the spherical pulses of the flow sensor 120 until the frequency reaches the point P. Therefore, the refrigerator controller 150 controls the valve device driver 140 by controlling the valve device driver 140 when the count value of the spherical pulse input from the photocoupler 170 is equal to the set value after starting the water supply operation to the tray. ) To stop the water supply operation.

In the water supply control apparatus of the refrigerator ice maker according to another conventional embodiment, when the water pressure of the ice making water supplied from the external water source increases linearly, the ice making water may be supplied to the tray by the set amount.

However, the deicing water supplied from the external water supply source flows into the flow sensor 120 and generates frictional resistance with the impeller 160 according to the flow rate. As a result, the pulse frequency does not increase proportionally. As the pulse frequency decreases exponentially as described above, an error occurs in the water supply amount of the ice making water supplied to the tray. Accordingly, when the ice water is excessively watered, the water level rises above the cells of the tray, and iced ice is entangled with each other, so that the ice is not properly formed, and when the ice water is insufficiently watered, the size of the iced ice is small. There was a problem.

SUMMARY OF THE INVENTION An object of the present invention is to provide a water supply control apparatus and method for a refrigerator ice maker that can supply a tray with a predetermined amount of ice making water without regard to the water pressure fluctuation of the ice making water supplied from an external water supply.

1 is a longitudinal sectional view of a refrigerator provided with a conventional automatic ice maker.

Figure 2a is a block diagram of a water supply control device of a refrigerator ice maker according to a conventional embodiment,

FIG. 2B is a perspective view schematically illustrating the dip switch of FIG. 2A;

Figure 3a is a block diagram of a water supply control device of a refrigerator ice maker according to another embodiment of the prior art,

3B is a circuit diagram showing a detailed configuration of the flow sensor of FIG. 3A;

4 is a view showing the pulse frequency of the flow sensor according to the water pressure;

5 is a configuration diagram of a water supply control device for a refrigerator ice maker according to the present invention;

6 is an operation flowchart showing a water supply control method of a refrigerator ice maker according to an embodiment of the present invention;

7 is a flowchart illustrating a water supply control method of a refrigerator ice maker according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

21: operation panel 22: flow sensor

23: valve device 24: valve device drive unit

25: refrigerator control unit 26: microcomputer

27: storage unit 28: timer

An object of the present invention as described above is provided with a flow sensor for detecting the water supply amount of the ice-making water supplied from the external water source and outputs a spherical pulse, the water supply to the tray ice-making water in response to the user's key input through the operation panel unit A water supply control apparatus of a refrigerator ice maker for controlling an operation, comprising: a timer for counting a water supply time of ice making water supplied from the water supply source; A valve device for controlling ice-making water installed and supplied to a water supply hose connecting the water supply source and the tray; A valve device driving unit for driving the valve device; And determining a supply water pressure of the ice making water supplied from an external water supply source according to the pulse frequency of the flow sensor when the user selects the automatic ice making function through the operation panel, and sets the ice making water by a set amount according to the determined supply water pressure. It is achieved by a refrigerator control unit for controlling the valve device drive unit to be supplied to the tray.

The flow sensor of the present invention generates a spherical pulse according to the ice-making water supplied from the external water supply source, the friction sensor is generated as the water pressure is increased, the pulse sensor is exponentially reduced.

Flow sensor according to an embodiment of the present invention is a flow sensor is installed in the water supply hose and the impeller rotated by the ice making water supplied from an external water supply source, and the light emitting diode and phototransistors respectively installed on the front and rear of the impeller And a transistor connected to the formed photocoupler and the phototransistor.

An object of the present invention as described above in the water supply control method of the refrigerator ice maker for controlling the operation of supplying the ice-making water to the tray in accordance with the water supply amount of the ice-making water supplied from the external water source, the key signal input by the user interpreted A water supply determination step of determining whether the water supply operation is started; A valve device opening step of opening a valve device installed in a water supply hose when a water supply operation is started as a result of the determination of the water supply determination step; A pulse sampling step of sampling a spherical pulse output by the flow sensor according to the amount of ice-making water supplied when the water supply operation is started by the valve device opening step; A supply water pressure determining step of determining a supply water pressure of the ice making water according to a pulse frequency of the flow sensor corresponding to the water supply of the ice making water; A water supply completion determination step of determining whether ice making water is supplied to the tray by a set amount based on the supply water pressure calculated by the supply water pressure calculating step; And a valve device closing step of closing the valve device when the ice making water is supplied by the set amount as a result of the determination of the water supply completion determination step.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

5 is a block diagram of a water supply control apparatus of the refrigerator ice maker according to the present invention. As shown, the present invention provides a control panel 210 having a plurality of function keys for the user to select the operating function of the refrigerator, including the automatic de-icing function, and a lighting lamp for indicating a selection state of the corresponding function keys; Flow rate sensor 220 for detecting the water supply amount of the ice-making water supplied from the external water supply source and outputs a spherical pulse, and the valve device 230 is installed in the water supply hose connected to the external water source to adjust the amount of ice-making water supplied to the tray 230 ), The valve device driver 240 for driving the valve device 230, and when the user selects the automatic ice making function, determines the water pressure of the ice making water supplied from an external water supply source according to the pulse frequency of the flow sensor. The refrigerator control unit 2 controls the valve device driving unit 240 to supply the ice making water to the tray according to the determined water pressure of the ice making water. 50 and a timer 280 for counting a water supply time of the ice making water supplied to an external water supply source under the control of the refrigerator control unit 250.

The flow sensor 220 rotates the impeller according to the water pressure of the ice-making water supplied from the external water supply source, and outputs the spherical pulse according to the refrigerator control unit 250. The refrigerator control unit 250 samples the spherical pulses input from the flow sensor 220 to determine the water pressure of the ice making water currently supplied to control the water supply operation, and the ice making water supplied from an external water supply source. Storage unit 270 having a first table corresponding to the pulse frequency of the flow sensor 220 according to the water pressure of the flow rate, and a second table corresponding to the water supply time according to the water pressure of the ice-making water supplied from the external water supply source Is done.

When the automatic deicing function is selected by the user, the microcomputer 260 controls the valve device driver 240 to start a water supply operation for supplying ice making water to an tray from an external water supply. In addition, since the pulse frequency according to the water pressure decreases exponentially as shown in (b) of FIG. 4, the microcomputer 260 supplies the water supply amount of the ice making water currently supplied according to the pulse frequency generated from the flow sensor 220. Decide That is, the microcomputer 260 determines the water pressure of the ice-making water currently supplied by sampling the spherical pulses of the flow sensor 220. The water supply operation is controlled by calculating the total cumulative value of the spherical pulses required to supply the ice making water to the tray according to the water pressure, or by controlling the water supply time required to supply the ice making water to the tray.

For example, when the water supply operation is controlled based on the total cumulative value of the spherical pulses according to water pressure, the microcomputer 260 performs sampling on the spherical pulses of the flow sensor 220 and inputs the spherical pulses for a predetermined time. A number corresponding to the set amount of the ice making water supplied to the tray under the condition that the ice water is supplied at the determined pressure by reading the water pressure from the first table of the storage unit 270 based on the count value. Compute the total number of pulses of the pulse. Thereafter, the microcomputer 260 determines that the sum of the spherical pulses counted through sampling matches the calculated total number of pulses, and determines that the ice making water of the set amount is supplied to the tray to stop the water supply operation. The driving unit 240 is controlled. Accordingly, the valve device 230 is closed to block the ice making water supplied from the external water supply.

On the other hand, in the case of controlling the water supply operation based on the water supply time according to the water pressure, the microcomputer 260 samples the rectangular pulses of the flow sensor 220 and supplies until the predetermined number of rectangular pulses are input. Counts the time, reads and determines the water pressure from the second table of the storage unit 270 based on the count value, and corresponds to the set amount of the ice making water supplied to the tray under the condition that the ice water is supplied at the determined water pressure. If the cumulative time counted from the time when the water supply operation is started through the timer 280 coincides with the calculated water supply time after calculating the water supply time, it is determined that the set amount of ice making water is supplied to the tray and the water supply operation is stopped. In order to control the valve device driver 240. Accordingly, the valve device 230 is closed to block the ice making water supplied from the external water supply.

Hereinafter, a water supply control method of the refrigerator ice maker according to the present invention will be described with reference to FIGS. 6 and 7.

6 is an operation flowchart showing a water supply control method of a refrigerator ice maker according to an embodiment of the present invention. First, when the user selects an automatic ice making function key corresponding to the automatic ice making function among the function keys provided in the operation panel unit 210, the microcomputer 260 supplies water according to a key signal input from the operation panel unit 210. It is determined whether to start (step 101). If the input key signal does not correspond to the automatic de-icing function key, the microcomputer 250 is supplied from an external water supply when the input key signal corresponds to the automatic de-icing function key. The valve driving device 240 is controlled to open the valve device 230 so that the deicing water may be supplied to the tray (step 102). Subsequently, the microcomputer 250 samples the spherical pulses input from the flow sensor 220 (step 103). Subsequently, the microcomputer 250 determines whether a predetermined time has elapsed after starting sampling (step 104). If the determination result of step 104 does not pass a predetermined time has elapsed, the process returns to step 103 in order to continue sampling the old pulse, whereas if the determination result of step 104 has elapsed a predetermined time, the previously stored first table In step 105, the supply water pressure corresponding to the count value obtained by counting the spherical pulses for a predetermined time obtained through sampling is determined. Subsequently, the microcomputer 250 calculates the total number of pulses of the spherical pulses corresponding to the set amount of the ice making water supplied to the tray based on the determined supply water pressure (step 106). Subsequently, the microcomputer 250 determines whether the accumulated value obtained by accumulating the spherical pulses so far is the total number of pulses calculated through sampling (step 107). If the cumulative value is not the total number of pulses in step 107, the microcomputer 260 determines that the ice making water is supplied to the tray below the set amount, and continuously samples the spherical pulses of the flow sensor 220 (the Step 108). If the cumulative value is the total number of pulses in step 107, the microcomputer 260 determines that the ice making water is supplied to the tray by the set amount, and controls the valve device driver 240 to stop the water supply operation. The valve device 230 is closed (step 109).

7 is a flowchart illustrating a water supply control method of a refrigerator ice maker according to another embodiment of the present invention. First, when the user selects an automatic ice making function key corresponding to the automatic ice making function among the function keys provided in the operation panel unit 210, the microcomputer 260 supplies water according to a key signal input from the operation panel unit 210. It is determined whether to start (step 201). If the input key signal does not correspond to the automatic de-icing function key, the microcomputer 250 is supplied from an external water supply when the input key signal corresponds to the automatic de-icing function key. The valve driving device 240 is controlled to open the valve device 230 so that the deicing water may be supplied to the tray (step 202). Subsequently, the microcomputer 250 starts the counting operation of the water supply time by operating the timer 280 (step 203). Subsequently, the microcomputer 260 samples the spherical pulses input from the flow sensor 220 (step 204). Subsequently, the microcomputer 250 determines whether the number of pearls counted through sampling is a predetermined number (step 205). If the determination result of the step 205 is smaller than the predetermined number, the flow returns to the step 204 to continue counting the spherical pulses, while if the number of pulses counted according to the determination result of the step 205 matches the predetermined number, the microcomputer 260 ) Is determined by reading the supply water pressure from the second table of the storage unit 270 according to the supply time required until reaching a certain number (step 206). Subsequently, the microcomputer 260 calculates a water supply time corresponding to the set amount of ice making water supplied to the tray based on the determined supply water pressure (step 207). Subsequently, the microcomputer 260 determines whether the accumulated time counted through the timer 280 is a calculated water supply time (step 208). If the cumulative time counted as a result of the determination in step 208 is not the calculated water supply time, the microcomputer 260 determines that the ice-making water is supplied to the tray below the set amount, and returns. If the cumulative time counted as a result is the water supply time, the microcomputer 260 determines that the ice-making water is supplied to the tray by the set amount, and controls the valve device driver 240 to stop the water supply operation. Close 230 (step 209).

As described above, the present invention determines the water supply pressure from the external water supply source according to the pulse frequency of the flow sensor, and then drives the valve device installed in the water supply hose based on the water supply pressure, thus making ice at any time without regard to the hydraulic pressure fluctuation. Water can be supplied. Therefore, the present invention has an effect of preventing the ice-making water from being excessively watered to entangle the iced ice, thereby inhibiting the ice-making operation or reducing the size of the iced iced water due to insufficient water supply of the ice-making water.

Claims (7)

Water supply of the refrigerator ice maker which detects the water supply amount of the ice making water supplied from an external water supply and outputs a rectangular pulse, and controls the operation of supplying the ice making water to the tray in response to a user's key input through the operation panel. In the control unit, A timer for counting the water supply time of the ice making water supplied from the water supply source; A valve device for controlling ice-making water installed and supplied to a water supply hose connecting the water supply source and the tray; A valve device driving unit for driving the valve device; And When the user selects the automatic deicing function through the operation panel, the supply water pressure of the ice making water supplied from the external water supply source is determined according to the pulse frequency of the flow sensor, and the ice making water is set to the tray according to the determined supply water pressure. And a refrigerator control unit for controlling the valve unit driving unit so as to be supplied to the water supply controller of the refrigerator ice maker. 2. The refrigerator of claim 1, wherein the refrigerator control unit controls a water supply operation by sampling a spherical pulse input from the flow sensor to determine a water pressure of ice making water currently supplied, and a water pressure of ice making water supplied from an external water source. Water supply control of the refrigerator ice maker comprising a first table corresponding to the pulse frequency of the flow sensor according to the flow sensor and a second table corresponding to the water supply time according to the water pressure of the ice-making water supplied from an external water supply source Device. In the water supply control method of the refrigerator ice maker for controlling the operation of supplying the ice-making water to the tray in accordance with the water supply amount of the ice-making water supplied from the external water source, A water supply judging step of determining whether a water supply operation is started by analyzing a key signal input by a user; A valve device opening step of opening a valve device installed in a water supply hose when a water supply operation is started as a result of the determination of the water supply determination step; A pulse sampling step of sampling a spherical pulse output by the flow sensor according to the amount of ice-making water supplied when the water supply operation is started by the valve device opening step; A supply water pressure determining step of determining a supply water pressure of the ice making water according to a pulse frequency of the flow sensor corresponding to the water supply of the ice making water; A water supply completion determination step of determining whether ice making water is supplied to the tray by a set amount based on the supply water pressure calculated by the supply water pressure calculating step; And And a valve device closing step of closing the valve device when the ice-making water is supplied to the tray by a predetermined amount as a result of the water supply completion determination step. The method of claim 3, wherein the determining of the supply pressure is characterized in that the supply water pressure corresponding to the count value of the rectangular pulse obtained by sampling the rectangular pulse of the flow sensor for a predetermined time is read and determined from a first stored table. Water supply control method of refrigerator ice maker. The method of claim 3, wherein the determining of the supply pressure is performed by reading the supply water pressure from a second stored table according to the supply time required until the count value of the counting pulse of the flow sensor reaches a predetermined number. Water supply control method of the refrigerator ice maker, characterized in that. The water supply completion determination step according to claim 3, wherein the total number of pulses of the flow sensor for supplying a predetermined amount of ice making water to the tray based on the determined supply water pressure is calculated and counted from the time of starting the water supply operation. And determining whether the accumulated value of the flow sensor is the calculated total number of pulses. The water supply completion determination step according to claim 3, wherein the water supply time corresponding to the set amount of the ice making water supplied to the tray is calculated based on the determined water supply pressure, and the accumulated time counted from the time when water supply operation is started through a timer is performed. The water supply control method of the refrigerator ice maker, characterized in that it comprises the step of determining whether the calculated water supply time.