KR100204649B1 - Water supply control device and method of ice machine - Google Patents

Abstract

The present invention relates to a water supply control device and method for an automatic ice maker for quantitative water control in an automatic ice maker. The water supply control device according to the present invention includes a microcomputer (20) and a water supply motor driver (50) for automatic ice making control and water supply control. And a water supply motor 60, a water supply motor current detection unit 70, and a display unit 80. The water supply control method according to the present invention drives a water supply motor in which a water supply acts as a load and sets a current amount flowing in the water supply motor for a predetermined time. Integrating and detecting the unit, and detecting that the amount of water to be supplied to the ice making container is insufficient when the detected current amount is smaller than the first reference current amount, stopping the driving of the water supply motor and displaying a warning of insufficient water supply. If the detected current amount is larger than the first reference current amount, the second current value is repeatedly accumulated and detected in a predetermined time unit, and the accumulated amount is the second predetermined value. Determining whether or not the quasi-current amount or more, and if the cumulative amount is greater than the second reference current amount, determining that the appropriate amount is supplied to the water supply container and stops the drive of the water supply motor, the quantitative water supply control with a simple structure in the automatic ice maker Would be possible.

Description

APPARATUS AND METHOD FOR CONTROLLING WATER SUPPLY OF A AUTOMATIC DEICER

The present invention relates to a water supply control device and method for an automatic ice maker, and more particularly, to a water supply control device and method for an automatic ice maker that can automatically supply water to an ice making container at a predetermined amount during automatic ice making.

In general, the automatic ice maker in the refrigerator automatically cycles the ice making operation to freeze the ice, remove the ice from the ice making container, and supply water to supply the ice making container. Is a device that makes it.

On the other hand, in such an automatic ice maker, the conventional water supply control device includes a main water tank and an auxiliary water tank mounted thereunder, and draws a predetermined amount of water from the main water tank naturally introduced from the main water tank to the ice making container. Water.

At this time, the reason why the auxiliary water tank is provided separately is to perform the quantitative control by the driving time of the pump in order to limit the water supplied to the ice making container to the quantitative amount, even if the pumping for the same time depending on the amount of water remaining in the water tank Since this becomes different, the auxiliary water tank which always fills a predetermined amount of water is provided.

Therefore, since additional auxiliary water tanks are separately provided to control the water supply, an additional additional manufacturing cost is added and there is a problem in that the amount of water supplied to the ice maker is not accurately controlled.

SUMMARY OF THE INVENTION An object of the present invention is to provide a water supply control apparatus and method for an automatic ice maker that enables accurate control of water supply in an automatic ice maker.

The water supply control apparatus of the automatic ice maker according to the present invention has an ice making mode, an ice making mode, and a water supply mode, and controls automatic ice making, outputs a water supply control signal in the water supply mode, and accumulates the applied water supply motor current by a predetermined time unit. A microcomputer that outputs a warning control signal when the amount of water supply motor current integrated in a predetermined time unit is smaller than the first reference amount, and stops the output of the water supply control signal when the cumulative amount matches the second reference amount. A water supply motor driver for outputting a predetermined drive signal based on the water supply control signal, a water supply motor serving as a load and driven based on a drive signal from the water supply motor driver to supply water to the ice making container, and an amount of current flowing through the water supply motor. Feed water motor current detection unit for detecting and outputting the feed water motor current to the micro And a display unit for displaying a lack of water supply based on a warning control signal from the controller.

In addition, the water supply control method of the automatic ice maker according to the present invention is a method for controlling the amount of water supplied to the ice making container at the time of water supply in the automatic ice maker, driving the water supply motor acting as a load and the amount of current flowing through the water supply motor Integrating and detecting in a predetermined time unit, and if the detected current amount is smaller than the preset first reference current amount, recognizing that there is insufficient water to supply water to the ice making container, stopping driving of the water supply motor and displaying a warning of insufficient water supply. And if the detected current amount is greater than the first reference current amount, detecting and accumulating the current amount repeatedly in predetermined time units, and determining whether the accumulated amount is greater than or equal to the preset second reference current amount; Determining that water is supplied to the water supply container and stopping the operation of the water supply motor Characterized by the yirueojim hereinafter.

1 is a block diagram of a water supply control apparatus of an automatic ice maker in a refrigerator according to a preferred embodiment of the present invention.

2 is a schematic cross-sectional view of a water pump and a water tank for explaining a process of water supply by driving the water supply motor of FIG.

3 is a flowchart illustrating a water supply control process of an automatic ice maker in a refrigerator according to a preferred embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10: ice making temperature detector 20: microcomputer

30: moving motor driving unit 40: moving motor

50: feed water motor drive unit 60: feed water motor

70: water supply motor current detection unit 80: display unit

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the invention described below with reference to the accompanying drawings by those skilled in the art.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a water supply control apparatus for an automatic ice maker in a refrigerator according to a preferred embodiment of the present invention, and an ice making temperature detector 10, a microcomputer 20, an ice motor driving unit 30, and an ice motor 40. And a water feed motor driver 50, a water feed motor 60, a water feed motor current detector 70, and a display 80.

In such a configuration, the ice making temperature detector 10 detects the temperature of the ice making container and outputs a detection signal to determine whether the water supplied to the ice making container is frozen.

In addition, the microcomputer 20 determines whether the water is frozen based on a detection signal from the ice making temperature detector 10 in the ice making mode during the automatic ice making control, and if the water is frozen, that is, when the ice is frozen, to take out ice from the ice making container. Switch to the ribbing mode and output the ribbing control signal.

In addition, the microcomputer 20 switches to a water supply mode and outputs a water supply control signal for supplying water to the ice making container after the end of the ice breaking mode, and is applied to the A / D (Analog to Digital) port from the water supply motor current detection unit 70 described later. The water supply motor current amount signal to be integrated is accumulated and accumulated in units of a predetermined time (about 10 msec in the preferred embodiment of the present invention), and the predetermined first reference amount (in the preferred embodiment of the present invention) Less than about 80 mA), outputs a warning control signal and stops outputting the water supply control signal when the cumulative amount coincides with a preset second reference amount (about 57 A in the preferred embodiment of the present invention).

Meanwhile, the moving motor driver 30 outputs a predetermined driving signal based on the moving control signal from the microcomputer 20, and the moving motor 40 is driven based on the driving signal from the moving motor driver 30 to make ice. Take out the ice from the container and prepare it for watering.

The water supply motor driver 50 outputs a predetermined drive signal based on the water supply control signal from the microcomputer 20, and the water supply motor 60 is driven based on the drive signal from the water supply motor driver 50 to make ice. The container is supplied with water, and as shown in FIG. 2, the meshed gear in the aberration pump is rotated to pump water from the water tank by the rotational force of the gear.

On the other hand, the feed water motor current detector 70 detects the amount of current that varies according to the load of the feed water motor 60, that is, the pumped water quantity, and outputs the feed water motor current amount to the microcomputer 20, a Hall element converter. The amount of current flowing in the feed water motor 60 is converted back into a magnetic voltage using a magnetic field and applied to the A / D port of the microcomputer 20.

In addition, the display unit 80 displays a warning by using a light emitting diode (LED) or the like to inform the user that the quantity of ice making is insufficient based on the warning control signal from the microcomputer 20.

Next, with reference to the flowchart of Figure 3 attached to the water supply control operation of the automatic ice maker according to a preferred embodiment of the present invention including the above-described configuration will be described in detail.

First, the microcomputer 20 applies a water supply control signal to the water supply motor driver 50 in the water supply mode through an ice making mode and an ice making mode during automatic ice making (step 300).

Then, the water supply motor 60 is driven based on the drive signal from the water supply motor driver 50 to start water supply to the ice making container.

At this time, the water supply motor current detection unit 70 detects the amount of current flowing through the water supply motor 60 and applies the water supply motor current amount signal to the microcomputer 20.

Next, the microcomputer 20 determines whether the initial water supply motor current amount signal from the water supply motor current detection unit 70 is equal to or larger than the first predetermined reference current amount (step 302).

At this time, if the initial water supply motor current amount signal is smaller than the first reference current amount, it is recognized that the amount of water to be supplied is insufficient and stops the output of the water supply control signal (step 304), and a warning control signal to inform the user that the water supply is insufficient. It applies to the display part 80 (step 306).

In other words, it can be seen that the water supply motor current is variable in response to a change in the water supply amount, which serves as a load of the gear in the aberration pump, as shown in FIG. 2, and accumulates such a change in the load regardless of the quantity in the water tank. By detecting, quantitative water supply is possible.

In addition, if such a load is less applied, the amount of water supply motor current is reduced, and thus, it is possible to detect a lack of water supply amount.

On the other hand, if the initial water supply motor current amount signal in step 302 is equal to or greater than the first reference current amount, the water supply motor current amount signal from the water supply motor current detection unit 70 is integrally integrated on the basis of a predetermined unit time (steps 308, 310), and the integrated current amount It is determined whether or not the second reference current is equal to or greater than step 312.

At this time, if the integrated current amount is smaller than the second reference current amount, the flow returns to the above-described steps 308 and 310 to continuously integrate and integrate the water supply motor current amount signal from the water supply motor current detection unit 70 on a predetermined unit time basis.

On the other hand, when the accumulated current amount up to the present time is equal to or greater than the second reference current in the above-described step 312, the microcomputer 20 determines that the water supply is completed in a proper amount in the water supply container, and stops output of the water supply control signal to terminate the water supply. (Step 314).

On the other hand, it will be understood by those skilled in the art that various changes and modifications can be made without departing from the spirit of the present invention.

As described above, according to the present invention, it is possible to control the quantitative water supply with a simple structure in the automatic ice maker.

Claims (3)

It has an ice making mode, an ice making mode, and a water supply mode and controls automatic ice making, outputs a water supply control signal in the water supply mode, accumulates the amount of water supply motor current applied in a predetermined time unit, and accumulates the amount of water supply motor current integrated in a predetermined time unit A mime comb 20 for outputting a warning control signal when the first reference amount is smaller than the preset first reference amount and stopping output of the water supply control signal when the accumulated amount coincides with the preset second reference amount; A water supply motor driver 50 for outputting a predetermined drive signal based on the water supply control signal from the microcomputer 20; A water supply motor 60 serving as a load and driven based on a drive signal from the water supply motor driver 50 to supply water to the ice making container; A water supply motor current detection unit 70 which detects an amount of current flowing through the water supply motor 60 and outputs a water supply motor current amount to the microcomputer 20; And a display unit (80) for displaying a water supply shortage based on a warning control signal from the microcomputer (20). The water supply control apparatus of an automatic ice maker according to claim 1, wherein the water supply motor current detection unit (70) uses a Hall element converter. A method for controlling the amount of water supplied to a deicing container at a time when water is supplied from an automatic ice maker, the method comprising: driving a water supply motor in which the water supply acts as a load and integrating and detecting the amount of current flowing through the water supply motor in a predetermined time unit; Recognizing that there is insufficient water for supplying water to the ice making container when the detected current amount is smaller than the first predetermined reference current amount, stopping driving of the water supply motor and displaying a warning that the water supply amount is insufficient; If the detected current amount is larger than the first reference current amount, detecting and accumulating the current amount repeatedly in predetermined time units and determining whether the accumulated amount is equal to or greater than the preset second reference current amount; And determining that the proper amount is supplied to the water supply container when the cumulative amount is equal to or greater than the second reference current amount, and stopping driving of the water supply motor.

Images