KR19990013143A - Ice control device and method for ice maker - Google Patents

Abstract

The present invention relates to an ice control device and a method of an ice maker, and an ice making plate rotatably installed in a freezer compartment for making water supplied from the water supply tank, an ice making sensor for sensing water temperature and ice temperature in the ice making plate, and A refrigerator ice maker including an ice motor that rotates the ice tray to separate ice formed in the ice tray, and determines whether the current state is the initial power supply or the power failure return state according to the temperature of the ice sensor during initial control. It is equipped with a control means for controlling one cycle standby operation.It detects the temperature of the ice making sensor during initial control and determines whether the current state is the initial power supply or the power failure return state. The ice making cycle is shortened by performing the ice removal operation when it arrives.

Description

Ice control device and method for ice maker

The present invention relates to an ice maker for a refrigerator, and more particularly, to an ice maker and a method for the ice maker which senses the temperature of the ice making sensor when the initial power is applied or when the power is restored and performs the ice-making operation without waiting for one cycle in case of a momentary power failure. It is about.

In general, an ice maker cools (de-ices) the water to be supplied (ice-making) to make ice, and separates (ices) this ice and automatically stores (saves) the ice-making cycle in general. have.

The first process is the watering process of initializing the ice maker and watering the ice tray, and the second process is ice making ice by freezing the water in the ice tray, and the third process is the ice formed on the ice tray. It is an ice-making process that separates from ice trays and puts them in ice storage containers.

As shown in FIG. 1, a refrigerator equipped with an ice maker that sequentially performs a series of ice making cycles, such as water supply → ice making → ice making, includes a freezer compartment and a refrigerating compartment (2, 4) for storing food in the upper and lower portions of the refrigerator main body 1. Is formed, and doors 6 and 8 for opening and closing the freezing chamber 2 and the refrigerating chamber 4 are provided on the front surface of the main body 1, respectively.

A water supply tank 10 is provided in the refrigerating chamber 4 to supply water for ice making. An ice making unit described below is used to supply water in the water supply tank 10 to the lower side of the water supply tank 10 through a water supply pipe 14. A water supply means 12 (water supply valve or water supply motor) for supplying water to the dish is provided.

In the freezing chamber (2) is provided with an ice making plate (16) for ice-making water supplied from the water supply tank (10) to be partitioned into a plurality of spaces to make ice (I). An ice making sensor 18 is attached to a lower end of the ice making plate 16 to detect the water temperature or the ice temperature, and on one side of the ice making plate 16, ice (I) formed in the ice making plate 16 is separated and stored later. An ice motor (not shown) is installed to rotate the ice tray 16 to be stored in a container.

In addition, an evaporator 22 is installed at a lower right side of the ice making plate 16 to heat the blown air to cold air, that is, cold air by latent heat of evaporation of the refrigerant. 22 is provided with a cooling fan 26 rotating in accordance with the driving of the fan motor 24 to circulate the cold air heat exchanged by the 22 to the periphery of the ice tray 16 to ice the water stored in the ice tray 16. have.

In addition, a storage container 28 for storing the ice I iced by the cooling fan 26 is installed at the lower portion of the ice tray 16, and the storage container at one side of the ice tray 16. The ice level detection lever 30 for detecting the amount of ice I stored in the 28 is rotatably installed around the hinge point 31, and the storage amount is formed at one end of the ice level detection lever 30. An ice detection switch 32 which is turned on / off by an ice level detection lever 30 which moves up and down in accordance with the amount of ice I stored in the container 28 is provided.

In the ice maker configured as described above, it is determined whether the ice tray 16 is horizontal when the initial power is applied or the power failure is restored, and the ice tray 16 is rotated forward in a microcomputer (not shown) to maintain the ice tray 16 horizontally. If water is supplied to the ice making plate 16 while waiting for a cycle (about 2 hours), ice making is performed.

After the waiting time of one cycle has elapsed, when the temperature of the ice making plate 16 is detected and the temperature reaches the ice-making operation temperature, the ice-making motor is rotated in reverse to perform the ice-making (initial ice-making mode).

When the ice is completed in the initial ice making cycle, the water supply motor 12 is driven to supply water from the water supply tank 10 to the ice making plate 16 through the water supply pipe 14, and at this time, water supply to the ice making plate 16. The temperature change of the water is detected by the ice making sensor 18 to determine whether normal water supply is completed.

When the water supply is completed, the cool air in the freezer compartment 2, which is heat-exchanged in the evaporator 22 by the cooling fan 26 that rotates as the fan motor 24 is driven, is circulated around the ice tray 16 and the ice tray 16 The water supplied to) starts to be iced, and at this time, a temperature of the ice tray 16 that changes is determined by the ice maker 18 to determine whether ice making is completed.

When the ice is completed, the ice (I) in the ice tray 16 is rotated while waiting for a predetermined time (about 5 minutes) in order to ensure the stability of the ice, and rotating the ice tray 16 according to the driving of the ice motor. The ice making cycle is repeatedly executed while falling to the ice storage container 28 to perform the ice storage operation stored in the storage container 28.

By the way, in the initial control method of the conventional ice maker, after one cycle unconditionally waits when the initial (first) power is applied or when the power failure is performed, if the ice condition occurs in the next step, the ice is operated. Even if a momentary power failure occurs, there is a problem in that an ice making cycle is lengthened by waiting for one cycle.

Accordingly, the present invention has been made to solve the above problems, and by detecting the temperature of the ice making sensor during the initial control to determine whether the current state is the initial power supply or the power failure return state, do not wait for one cycle in case of momentary power failure. It is an object of the present invention to provide an ice maker and a method for controlling an ice maker that shortens an ice making cycle by performing an ice making operation immediately when an ice temperature is reached.

In order to achieve the above object, the ice-making control device of the ice maker according to the present invention is installed in a freezing chamber so as to rotate, an ice-making plate for ice-making water supplied from the water supply tank, an ice-making sensor for detecting water and ice temperature in the ice-making plate; In the ice maker for refrigerators consisting of an ice motor for rotating the ice tray to separate the ice formed in the ice tray, it is determined whether the current state is the initial power supply or the power failure return state in accordance with the temperature of the ice sensor during the initial control It characterized in that it comprises a control means for controlling the one-cycle standby operation.

In addition, the ice-making control method of the ice maker according to the present invention is a horizontal discrimination step for determining whether the ice making plate horizontally in accordance with the on / off signal of the horizontal switch and the ice detection switch during the initial control, and the ice making plate is horizontal If it is determined that it is not determined, the horizontal holding step for keeping the ice tray horizontally by rotating the ice motor forward by the control means of the control means, and detecting the temperature of the ice making sensor by detecting the temperature of the ice making sensor if the ice tray is horizontal. If the temperature discriminating step and the temperature of the ice making sensor in the temperature discriminating step are more than the predetermined temperature, the standby step waits for one cycle because the initial power is applied, and if the temperature of the ice making sensor is less than the predetermined temperature in the temperature discriminating step, the power failure is returned. Therefore, the ice-making step of performing the ice-making operation when the temperature of the ice-making sensor reaches the ice-making temperature without waiting for one cycle. Characterized in that consisting of.

1 is a schematic longitudinal cross-sectional view of a conventional ice maker for a refrigerator;

2 is a control block diagram of an ice making control apparatus for an ice maker according to an embodiment of the present invention;

3 is a flowchart showing an operation procedure of an initial ice removal control of an ice maker according to the present invention.

Explanation of symbols on the main parts of the drawings

12: water supply means 16: ice tray

18: Ice making sensor 20: Ice motor

28: ice storage container 32: inspection switch

34: horizontal switch 36: test switch

52: position detecting means 54: control means

56: temperature sensing means 60: moving motor driving means

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

As shown in FIG. 2, the power supply unit 50 receives a commercial AC voltage supplied from an AC power terminal (not shown), and converts it into a predetermined DC voltage (load driving power source and microcomputer driving power source) required for the operation of the ice maker. In addition, the position detecting means 52 is a sensing switch 32 means for detecting the amount of storage of the ice storage container 28, a horizontal switch 34 means for detecting the position of the ice tray 16, and the ice maker It consists of a test switch 36 or the like which is a means for inspecting whether or not an ice making cycle composed of water supply, ice making and ice making is performed correctly.

The control unit 54 receives the DC voltage (microcomputer driving power) output from the power supply unit 50 to initialize the ice maker, and also the overall ice making according to the on / off signal of the ice sensor switch 32. As a microcomputer for controlling the operation, the control means 54 determines whether the current state is the initial power supply or the power failure return state according to the temperature of the ice making sensor 18 at the time of initial control to control the standby operation of one cycle. do.

In addition, the temperature sensing means 56 is a temperature sensing circuit composed of an ice making sensor 18 or the like to detect the water temperature or the ice temperature in the ice making plate 16 and output it to the control means 54, and the water supply driving means 58 The water supply means 12 is driven to control the water supply means 12 so that water is supplied from the water supply tank 10 to the ice making plate 16 by receiving the control signal output from the control means 54.

The ice motor driving means 60 receives the control signal output from the control means 54 and stores the ice I formed in the ice making plate 16 in the ice storage container 28 when it is separated. Drive control.

Hereinafter, the operation and effect of the icemaker and the method of the ice maker configured as described above.

FIG. 3 is a flowchart showing the operation of the initial ice-making control of the ice maker according to the present invention. In FIG. 3, S denotes a step.

First, when power is applied to the refrigerator, in step S1, the control means 54 detects the on / off signal of the horizontal switch 34 which is a horizontal sensing means and the sensing switch 32 which is a ice sensing means, and then makes the ice tray 16 a. If it is not horizontal (if NO), the horizontal switch 34 or the detection switch 32 is turned on, and a low signal is applied to the control means 54. The control means 54 returns to the step S1 while rotating the moving motor 20 forward until the horizontal switch 34 and the ice detection switch 32 are both off so that the ice making plate 16 is in a horizontal state. The operation below S1 is repeated.

As a result of the discrimination in step S1, when it is horizontal (YES), both the horizontal switch 34 and the detection switch 32 are turned off, and high and high signals are applied to the control means 54. Further, the control means 54 controls the ice motor driving means 60 to stop the ice motor 20 to keep the ice tray 16 in a horizontal state.

If the ice tray 16 is returned to the horizontal state or is initially determined to be horizontal, at step S4, the voltage value of the ice maker 18 is detected and the temperature value of the ice maker 18 is determined by the temperature sensing means 56. In step S5, it is determined whether the temperature value of the ice making sensor 18 is equal to or less than a predetermined temperature T1 (about -5 ° C).

As a result of the determination in step S5, when the temperature value of the ice making sensor 18 is equal to or lower than the predetermined temperature T1 (YES), the refrigerator continues to operate in a normal routine, and the ice maker also continuously performs water supply → ice making → ice making. In the meantime, a momentary power outage occurs in a very short time, and the temperature value of the ice making sensor 18 is completely de-iced, so it is not an ice making condition, but it forms a temperature range much lower than the temperature of the ice making sensor 18 after water supply is completed. .

Therefore, in step S6, ice-making is continued without waiting for one cycle (about 2 hours), and then it is determined whether the temperature value of the ice-making sensor 18 reaches the ice-making temperature (temperature data is about -9 ° C), If the ice temperature has not been reached (NO), the operation of step S6 or less is repeated until the ice temperature is reached.

As a result of the discrimination in step S6, when the ice temperature is reached (YES), the flow advances to step S7 to determine whether the ice temperature has elapsed and a predetermined time (T2; about 5 minutes) has elapsed. If it has not elapsed (NO), the operation of step S7 or less is repeated until the predetermined time T2 has elapsed.

As a result of the discrimination in step S7, when the predetermined time T2 has elapsed (YES), the control means 54 separates the iced ice I and stores it in the storage container 28. The control signal is output to the moving motor driving means 60.

Thus, the ice motor driving means 60 receives the control signal output from the control means 54 and drives the ice motor 20 to rotate the ice making plate 16 while the ice making ice in the ice making plate 16 ( I) falls into the storage container 28 and is stored in the storage container 28.

At this time, in step S9, it is determined whether or not the ice is completed according to the driving of the ice motor 20, and when the ice is not completed (NO), the process returns to the step S8 and repeats the operation of the step S8 or less, and the ice is completed. (YES), the water supply routine to stop the moving motor 20 in accordance with the control of the control means 54 in the moving motor driving means 60 to stop the moving operation and proceed to step S10 to start a new ice making cycle. Return to.

On the other hand, as a result of the determination in step S5, if the temperature value of the ice making sensor 18 is equal to or higher than the predetermined temperature T1 (when NO), the control means 54 sets the temperature value of the ice making sensor 18 to a value similar to room temperature. Determines that it is the initial power supply state, proceeds to step S11, waits for one cycle (about 2 hours), and proceeds to step S6 to repeat the operation of step S6 or less.

According to the ice-making control apparatus and method thereof of the ice maker according to the present invention as described above, if the instantaneous power failure by detecting the temperature of the ice-making sensor during the initial control and determining whether the current state is the initial power supply or the power failure return state. When the temperature is reached without waiting for the cycle, the operation is performed immediately to reduce the ice making cycle.

Claims (4)

Rotating in the freezer compartment to rotate the ice making plate to defrost the water supplied from the water supply tank, the ice sensor for detecting the water temperature and ice temperature in the ice plate, and to rotate the ice plate to separate the ice formed in the ice plate In the ice maker for refrigerators consisting of an ice motor, And control means for controlling one cycle standby operation by determining whether the current state is the initial power supply or the power failure return state according to the temperature of the ice making sensor during the initial control. The method of claim 1, And the control means performs the ice-making operation when the temperature of the ice-making sensor reaches the ice-making temperature without waiting for one cycle if it is determined that the current state is the reset of the power failure. The method of claim 1, And the control means waits for one cycle if it is determined that the current state is the initial power-on, and performs the ice-making operation when the temperature of the ice-making sensor reaches the ice-making temperature. A horizontal discrimination step for determining whether the ice making plate is horizontal according to the on / off signals of the horizontal switch and the ice detection switch during initial control; A horizontal holding step of keeping the ice making plate horizontal by rotating the ice motor forward under control of a control means when it is determined that the ice making plate is not horizontal in the horizontal discriminating step; A temperature discrimination step of detecting a temperature of the ice making sensor and determining whether the ice making plate is horizontal or less when the ice making plate is horizontal; In the temperature discrimination step, if the temperature of the ice making sensor is greater than or equal to a predetermined temperature, a standby step of waiting for one cycle since the initial power is applied; In the temperature discriminating step, if the temperature of the ice making sensor is less than a predetermined temperature, the power failure is returned. Thus, the ice making step is performed without performing a cycle and performing an ice making operation when the temperature of the ice making sensor reaches the ice making temperature. Ebbing control method.