KR100661831B1 - The water supply perception method of an ice-maker - Google Patents

Abstract

The present invention relates to a water supply detecting method of an ice maker, and an object of the present invention is to provide a water supply detecting method of an ice maker that can determine whether water supply is normally performed using an ice making temperature sensor attached to an ice manufacturing container.

In addition, if the water supply is not made smoothly, by providing a display to the user that there is an error in the water supply to provide a water supply detection method of the ice maker to make it easy for the user to determine whether or not.

To this end, the present invention is characterized by detecting the temperature of the ice making container, and determines whether the water supply state is normal according to whether the temperature of the ice making container after water supply is higher than the temperature of the ice making container before water supply.

Description

The water supply perception method of an ice-maker}

1 is a cross-sectional view illustrating an internal structure of a refrigerator according to one embodiment of the present invention.

FIG. 2 is a cross-sectional view illustrating an internal structure of the automatic ice maker shown in FIG. 1.

3 is a block diagram illustrating components of the automatic ice maker shown in FIG. 2.

4 is a flowchart illustrating a water supply state detection method of the automatic ice maker shown in FIG. 2.

5 is a flowchart illustrating a water supply state sensing method of the automatic ice maker shown in FIG. 2.

Explanation of symbols on the main parts of the drawings

10: automatic ice maker

11: ice container

12: water supply pipe

14: ice making temperature sensor

30: micom

34: display unit

The present invention relates to a water supply detection method of an ice maker, and more particularly, to a water supply detection method of an ice maker that can determine the presence or absence of water supply conditions using a temperature sensor attached to the ice supply container.

In general, an automatic ice maker is installed in a freezer compartment of a refrigerator to automatically supply ice-making water to a tray and check the ice-making state so that ice-making ice is automatically removed from the tray and loaded into a storage container when ice-making is completed. As a result, the user does not need to perform a separate operation for the ice making.

Recently, as refrigerators become more advanced and larger, and ice consumption increases, automatic ice makers are becoming an essential component of refrigerators.

Such a conventional automatic ice maker starts to be driven when the power is supplied to the refrigerator, and the temperature inside the refrigerator is gradually lowered to a temperature that can make ice. When the temperature is low enough, the ice making temperature sensor in the automatic ice maker senses the temperature and starts the ice making operation.

First, feed water from the water supply pipes, such as water pipes and water purifiers, into the tray. When the water supply is complete, the water supplied by the cold chill in the refrigerator turns into ice. If the temperature detected by the ice making temperature sensor after a predetermined time is determined to be less than the set temperature, the ice is removed by rotating the motor installed in the automatic ice maker to remove the ice from the tray.

When the ice is completed, the tray is empty, so the water is supplied again and the ice making process is repeated.

On the other hand, in the operation of the ice maker, the water does not supply to the ice maker tray due to a defective water supply solenoid valve, or the water is not supplied to the ice maker tray due to the water supply pipe bending, leaking or clogging, etc. It may not work properly.

However, in such a case, there is a problem in that, in addition to the installation of a separate water quantity sensor in the ice maker to detect whether there is an error in the water supply, it is not easy to confirm that the operation error of the ice maker is due to water supply failure.

In addition, the user has a problem that it is difficult to recognize the cause of the problem when the ice maker is not made in the ice maker, so that a visit of the service staff is requested.

The present invention is to solve the above-mentioned problems, an object of the present invention to provide a water supply detection method of the ice maker that can determine whether the water supply is normal by using an ice making temperature sensor attached to the ice production container.

In addition, if the water supply is not made smoothly, by providing a display that the user is abnormal in the water supply to provide a water supply detection method of the ice maker so that the user can easily determine whether the abnormality.

The present invention for achieving the above object senses the temperature of the ice making vessel, and determines whether the water supply state is normal according to the temperature of the ice making vessel.

In addition, when the temperature of the ice-making vessel after watering is higher than the temperature of the ice-making vessel before watering, characterized in that it is determined that the water supply state is normal.

In addition, if it is determined that the water supply state is bad, characterized in that for displaying the water supply failure state.

In addition, after the water supply state is determined to be defective, the water is periodically supplied to the ice making container, and characterized in that for sensing the temperature of the ice making container.

In addition, when the temperature of the ice making vessel rises after watering, it is determined that the water supply state is normal, characterized in that to release the display of the water supply failure state.

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

As shown in FIG. 1, a refrigerator according to the present invention includes a housing 1 having an open front, a freezer compartment door 2 and a refrigerator compartment door (not shown) hinged to an open front of the housing 1. In order to form an external appearance, the freezing compartment 4 and the refrigerating compartment (not shown) which are opened and closed by the freezing compartment door 2 and the refrigerating compartment door (not shown) are respectively provided inside the housing.

The rear wall of the housing 1 is provided with an evaporator 5 for generating cold air, and a compressor 6 for compressing a refrigerant is installed at the lower rear side of the housing 1, and a piece of a predetermined size is provided at the upper part of the freezing chamber 4. An automatic ice maker 10 for automatically making and supplying ice is installed.

2 and 3, the automatic ice maker 10 is provided with an ice manufacturing container (ICE-TRAY) 11 for supplying water to make ice, and is disposed below the ice manufacturing container 11 to make ice. Ice storage container 20 for storing the sculpted ice made in (11), and connected to the external water source and extends to the upper portion of the ice production container (11) to supply water for making ice to the ice production container (11) A water supply pipe 12 is provided.

In addition, an ice making temperature sensor 14 is installed at a lower predetermined position of the ice making container 11 to detect a temperature change of the ice making container 11 and determine a water supply state, an ice making state, and an ice state. It is provided with the full lever 13 in which a rotation position is controlled according to the ice load amount of the container 20. As shown in FIG.

The case 15 of the automatic ice maker 10 is equipped with an ice motor 33 for rotating the ice container 11 and an ice detection switch 35 that is turned on according to the degree of rotation of the ice lever 13. have.

In addition, the operating state of the power supply unit 31 for supplying a driving voltage to the automatic ice maker 10, the water supply solenoid valve 32 for adjusting the amount of water supplied through the water supply pipe 12, and the automatic ice maker 10 The display unit 34 to display to the user, and the microcomputer 30 for controlling each device of the automatic ice maker 10 is further included.

The automatic ice maker 10 configured as described above opens the water supply solenoid valve 32 to fill the ice manufacturing vessel 11 with the water supply pipe 12. At this time, the method of controlling the amount of water supplied to the ice manufacturing container 11 is to control the opening time of the water supply solenoid valve 32 and the method of detecting the water supply amount using a separate flow sensor (not shown). have.

When a predetermined time elapses after the water supply, the ice inside the ice container 11 is frozen by cold air circulating in the freezing chamber 4, and ice cubes are made. The ice making temperature sensor 14 is attached to the ice container 11. ) Can determine whether ice making is completed. When the temperature detected by the ice making temperature sensor 14 is lower than or equal to the set temperature, the microcomputer 30 determines that ice making is completed and rotates the ice making motor 33 in a predetermined direction. As described above, when the ice motor 33 is rotated, one side of the ice container 11 is caught on a step and no longer rotates, and the other side of the ice container 11 is continuously rotated by the ice motor 33. As a result, the ice container 11 is distorted. Therefore, the iced ice is separated from the ice manufacturing container 11 and automatically transferred to the ice storage container 20 to fill the ice storage container 20.

When the ice making process is repeatedly performed, the amount of ice loaded in the ice storage container 20 is increased, and the rotational position of the ice lever 13 is rotated according to the amount of ice loaded in the ice storage container 20. Will be different. The ice sensing switch 35 determines whether the ice storage container 20 is full of ice according to the rotational position of the ice lever 13, and turns on the ice detection switch 35 when the ice is filled. When the ice detection switch 35 is turned on, the microcomputer 30 stops the ice making by controlling each device.

On the other hand, the ice making temperature sensor 14 attached to the ice making container 11 can be determined whether the water supply to the ice making container 110 is normal. If the automatic ice making machine 10 operates normally, the ice making container. When water is supplied to 11, the temperature detected by the ice making temperature sensor 14 is increased, which is used by the fact that the temperature of the water supplied through the water supply pipe is higher than the temperature of the automatic ice maker 10. However, If water is not supplied to the ice manufacturing container 11 due to a failure of the accommodating solenoid valve 32, leakage of the water supply pipe 12, bending, or clogging, the temperature detected by the ice making temperature sensor 14 does not rise. In this way, the water supply state of the automatic ice maker 10 may be determined using the change in temperature detected by the ice making temperature sensor 14.

Hereinafter, a water supply detection method of an automatic ice maker will be described with reference to FIG. 4.

First, when power is supplied to the refrigerator through the power supply unit 31, the state of various sensors and switches are initialized to start the operation of the automatic ice maker 10. (S100) The microcomputer 30 operates within the refrigerator as the refrigerator is normally operated. Wait for each device of the automatic ice maker 10 for the time required to lower the temperature. (S110) After a predetermined time has elapsed, the temperature measured to measure the temperature of the ice container 11 using the ice making temperature sensor 14. It is determined whether the temperature has fallen enough to satisfy the ice making temperature conditions that can make ice (S120).

When the ice making temperature condition is satisfied, the ice making operation is started in earnest, and since the ice making apparatus of the automatic ice maker 10 is not known after the operation of the first refrigerator, it is not possible to determine whether the ice is normally started. After waiting for a predetermined time, when the ice making temperature sensor 14 is measured and the ice making condition is satisfied, the ice motor 33 is driven to move the ice in the ice container 11 to the ice storage container 20. A ribbing operation is performed (S130).

Thereafter, the microcomputer 30 opens the water supply solenoid valve 32 so that water is supplied from the water supply source such as a water pipe or a water purifier to the ice manufacturing container 11 (S140). 30) It is fixed inside and the time to be supplied varies depending on the water supply conditions. When the water supply is completed, the ice making temperature sensor 14 is used to detect the temperature of the ice container 11. It is determined whether the temperature of the ice production container 11 after the water supply is higher than the temperature of the ice production container 11 before the water supply. (S150) As a result of the determination, if the temperature of the ice production container 11 increases after the water supply, If the measured temperature of the ice making temperature sensor 14 is lower than the set temperature after a predetermined time, it is determined that ice making is completed, and the ice in the ice manufacturing container 11 is stored in ice. After moving to the vessel 20 is repeated by the above ice making process. (S110 ~ S130)

On the other hand, if the temperature of the ice production container 11 after the water supply is not higher than the temperature of the ice production container 11 before the water supply, the water supply to the ice production container 11 is tried again. It is determined once again whether the temperature of the container 11 is higher than the temperature of the ice production container 11 before water supply. (S180) If the temperature of the ice production container 11 rises after resupply, the water supply state is normal. After determining that the ice making process is performed (S190).

If the temperature of the ice production container 11 after resupply is still not higher than the temperature of the ice production container 11 before water supply, it is regarded that the water supply state is poor, and the microcomputer 30 controls the display unit 34 so that the water supply state is poor. (S200, S210)

Even after it is determined that there is a problem with water supply, the automatic ice maker 10 continues to operate as shown in FIG. 5.

The water supply solenoid valve 32 is controlled to supply a predetermined amount of water to the ice production container 11. (S22) Then, after the water supply, the temperature of the ice production container 11 is the temperature of the ice production container 11 before water supply. It is determined whether the temperature has risen. (S230) If the temperature does not rise, since the abnormality is maintained in the water supply state, it continues to display that the water supply is in a bad state, and periodically tries water supply.

On the other hand, if the temperature of the ice production container 11 after the water supply rises, it is determined that the water supply state is normal due to some cause of the water supply is resolved (S240), and the water supply failure display is also released (S250). The ice making process is normally performed.

In addition, when it is determined that the water supply state is bad, the corresponding data is stored in the EEPROM (not shown). When the water supply state returns to normal, the corresponding data stored in the EEPROM is also deleted. Alternatively, the contents of the defect may be deleted by a service engineer or a user through arbitrary operations.

As described in detail above, the present invention can easily determine the water supply failure state of the automatic ice maker using the ice making temperature sensor, it is possible to notify the user of the water supply failure state quickly to take measures accordingly.                     

In addition, even in case of poor water supply, it is possible to perform deicing quickly when the poor condition is released by continuously supplying water.

Claims (5)

Detects the temperature of the ice tray before and after water supply, It is determined whether the water supply state is normal according to the temperature change before and after the water supply of the ice making container, If it is determined that the water supply state is bad, water supply detection method of the ice maker, characterized in that for displaying the water supply failure state and to store the water supply failure data. The method of claim 1, The water supply detection method of the ice maker characterized in that the water supply state is determined to be normal when the temperature of the ice making vessel after watering is higher than the temperature of the ice making vessel before water supply. delete The method of claim 1, And periodically supplying water to the ice making container after the water supply state is determined to be inferior, and sensing a temperature of the ice making container. The method of claim 4, wherein If the temperature of the ice-making vessel after the water supply rises, it is determined that the water supply state is normal, the water supply failure state display is released and the stored water supply failure data characterized in that for deleting the stored water supply failure data.

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