KR100347022B1 - Structure and Control Method of Refrigerator Ice Maker - Google Patents

Abstract

The present invention relates to a control method of a refrigerator ice maker, and to detect whether or not a storage container portion in which ice is stored, and to perform an ice breaking operation so as to prevent the ice from pouring into the refrigerator when there is no storage container portion. It relates to a structure and a control method thereof.

According to the present invention, the ice making unit 10 for forming ice, the ice storage unit 20 for storing the ice iced in the ice making unit 10, and whether the ice stored in the ice storage unit 20 It comprises the ice-covering means 18 for detecting the vessel and the vessel detecting means 18 for determining the existence of the ice storage unit 20, the ice-covering means 18 and the storage vessel detection means 18 ) Is composed of a lever 18 is formed integrally, the lever 180 is in contact with the ice stored in the upper portion of the storage container 20 in accordance with the shanghai 18 and the storage container 20 And a vertical arm 18b in contact with the ice, and a control method of a refrigerator ice maker comprising an ice forming step, an ice making step for determining whether ice is frozen, a storage container judging step, and an ice control step. So there is no storage container. Is not been made ice-separation operation has the advantage of being prevented from pouring into the ice when the refrigerator.

Description

Structure and Control Method of Ice Maker for Refrigerator

The present invention relates to a refrigerator ice maker, and more particularly, to detect whether or not a storage container portion in which ice is stored, and to carry out an ice stroke to prevent ice from pouring into a refrigerator when there is no storage container portion. It relates to a structure and a control method thereof.

In general, according to the recent trend of improving living standards and the preference for large and multi-functional refrigerators, refrigerators having a relatively large capacity and having various functions are being shown. In recent years, a refrigerator having a freezer, a refrigerator compartment dispenser and an ice maker has been introduced. As the demand for refrigerators increases, so does its function. With reference to the drawings showing the structure of a conventional composite refrigerator provided with an ice maker as described above.

1 is a schematic structural diagram of a conventional combined refrigerator with an ice maker. As shown, the ice maker A is installed inside one side of the freezing compartment 1. The ice maker A has an ice making unit 2 that forms ice thereon, and a storage container 3 is installed below the ice maker A to store ice formed in the ice making unit 2.

On the other hand, the dispensing apparatus 4 is installed on the front surface of the freezing chamber door 1a, so that water or ice desired by the user can be easily taken out from the outside without opening the door 1a.

The ice maker A and the dispensing device 4 are connected to a water supply source (for example, a faucet) outside the refrigerator to receive water. That is, an external pipe 6a connected to the water supply source outside the refrigerator is installed through the rear wall of the refrigerating chamber, and a filter 5 is installed at one side of the external pipe 6a to supply water introduced through the external pipe 6a. It will be filtered. And, the other side of the filter (5) is connected to the inner pipe (6b), the water supply valve (7) is provided at the end of the inner pipe (6b).

The water supply valve 7 serves to control the water supplied to the ice maker A and the dispense device 4. That is, an ice maker pipe 6c connected to the ice maker A is installed at one side of the water supply valve 7, and a dispense pipe 6d connected to the dispense device 4 is installed at the other side. In the middle of the dispensing pipe 6d, a water tank 8 for storing water supplied to the dispensing device 4 is provided.

As configured as described above, the water delivered from the external water supply source can be delivered to the ice maker A and the dispensing device 4 through the pipe 6, the filter 5, and the water supply valve 7, respectively. .

Next, the structure of the ice maker A will be described in more detail with reference to FIG. 2. As shown, the ice maker A has an ice making unit 2 that forms ice thereon, and a storage container unit 3 is installed at the lower portion thereof to store the ice produced by the ice making unit 2.

Meanwhile, referring to the ice making unit 2, an ice making container 2a for forming ice, a temperature sensor 2b for detecting a temperature in the ice making container 2a, and ice formed in the ice making container 2a will be described later. It consists of a rotational force transmission (2c) for transmitting to the storage container (3) and an ice detection lever (2e) for determining whether the ice stored in the storage container (3) is ice.

That is, the end of the ice making container (2a) is connected to the axis of the rotational force transmission (2c) and the ice formed in the ice making container by rotating the ice making container (2a) 180 ° by the operation of the rotational force transmission (2c) It falls to this storage container part 3. Then, the detection lever (2e) is connected to the support (2d) located on one side of the rotational force transmitter (2c). The detection lever 2e is configured to move up and down the support 2d, so that the arm of the detection lever 2e can come into contact with ice in the storage container part 3, so that the storage container part 3 can be moved. It is possible to determine whether the ice stored inside the ice sheet is full of ice or not.

Next, ice formation and ice formed according to the structure of the ice maker A configured as described above will be described with reference to FIG. 3.

First, the water supply valve 7 is operated to supply water for forming ice into the ice making container 2a (step I). The water supply is made by passing the water delivered from the water supply valve 7 into the ice making container under the control of the microcomputer (step II). After the water supply is made, the ice making unit 2 is operated under the control of the microcomputer to make ice for a predetermined time (step III). At this time, after a predetermined time elapses, the temperature of the ice making container 2a is sensed by the temperature sensor 2b. If the temperature detected by the temperature sensor 2b is less than the set temperature, it is determined that ice making is completed, and the subsequent process is performed (step IV). That is, when it is determined that ice making is completed, the ice detection lever 2e is operated to determine whether the ice stored in the storage container part 3 is full of ice (step V).

If it is determined that the ice is not full, the rotational force transmitter 2c is operated to rotate the ice maker 2a 180 ° so that the ice formed in the ice maker 2a is transferred into the storage container part 3 ( Step VI). However, if it is determined that the inside of the storage container part 3 is full ice by the ice detection lever 2e, the ice ice stroke is performed only when the ice is not iced by periodically repeatedly inspecting it at a predetermined time without proceeding the ice ice stroke. After the ice stroke is performed as described above, water is supplied into the ice making container 2a by the adjustment of the water supply valve 7 to end the ice making cycle.

In the above process, the ice sensing stroke which detects whether or not the ice is covered by the ice detection lever 2e is configured to be performed every time before the ice. However, the detection method of the detection lever 2e simply determines whether or not the detection ice lever 2e is moved to the bottom and the ice is in contact with the arm of the detection lever 2e. That is, when the refrigerator is operated after cleaning or repairing or the user takes out the storage container part 3 to use ice, the detection lever 2e is operated to allow the ice stored in the storage container part 3 to be filled. Will be judged. At this time, even when the storage container part 3 does not exist, since there is no ice contacting the arm of the ice detection lever 2e, it is judged that it is not full ice and an ice-breaking operation is performed. Therefore, despite the case where the storage container 3 does not exist, the ice-breaking operation is performed, causing the ice to pour into the refrigerator.

When the storage container 3 does not exist in order to eliminate the above problems, the operation of the ice maker itself must be stopped in order to prevent the operation of the ice detection lever 2e in order to prevent the ice from pouring into the refrigerator. Therefore, the user has to stop the operation of the ice maker every time the storage container part 3 does not exist for cleaning or repairing.

The present invention is to solve the above problems, after determining whether or not by the operation of the ice level lever, if not in the ice to detect the existence of the storage container portion, if the storage container portion does not exist in the ebbing stroke It is an object of the present invention to provide a refrigerator ice maker structure and a control method thereof in which ice is not poured into the refrigerator by preventing this from being performed.

1 is a schematic structural diagram of a conventional combined refrigerator with an ice maker.

2 is a cross-sectional view of an ice maker showing the internal structure of a conventional ice maker.

Figure 3 is a flow chart showing the operation of the conventional ice maker.

Figure 4 is a cross-sectional view showing the internal structure of the ice maker according to an embodiment of the present invention.

5 is a flow chart showing the operation of the ice maker according to the present invention.

Explanation of symbols on the main parts of the drawings

10: ice maker 12: ice maker

14: temperature sensor 16: rotational force transmitter

17: support 18: ice detection lever

18a: sliding axis 18b: vertical arm

18c: horizontal arm 20: storage container

22: protrusion A: ice maker

According to a first aspect of the present invention for achieving the above object, an ice making unit for forming ice, an ice storage unit for storing the ice iced in the ice making unit, and whether the ice stored in the ice storage unit It is to provide a structure of a refrigerator ice maker comprising a means for detecting the ice and a container detecting means for determining the presence of the ice storage.

In addition, the ice-covering means and the storage container portion detecting means is formed integrally, so that the lever is moved up and down. The ice detection means is composed of a horizontal arm of the lever is moved to the lower portion of the predetermined distance and in contact with the ice stored in the upper portion of the storage container, the container detecting means, the lower portion of the lever is moved to the lower portion of the predetermined distance in contact with the storage container It should consist of vertical arms.

According to a second aspect of the present invention, in a refrigerator provided with an ice maker, an ice forming step of forming ice, and an ice making step of determining whether ice is present in the storage container after ice formation, In the ice making judgment step, when it is full ice, the storage container judging step for judging the existence of the storage container part periodically and repeatedly if it is not full ice, and when the storage container part exists, perform the ice-breaking operation and the storage container part does not exist. The present invention provides a control method of an ice maker for a refrigerator, which comprises an ice-breaking control step to prevent the ice-breaking operation from being performed.

In addition, the storage container sub-step determination step is configured to further comprise an alarm step notifying the user when the storage container does not exist.

Therefore, when the storage container is not present by the control method of the ice maker according to the present invention, there is an advantage in that ice is not prevented from being spilled into the refrigerator.

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

4 is a schematic cross-sectional view showing the structure of an ice maker according to the present invention. As shown, in the ice maker A according to the present invention, an ice maker 10 for forming ice is positioned at an upper portion, and a storage container for storing ice formed at the ice maker 10 at a lower portion thereof. The unit 20 is located.

First, looking at the structure of the ice making unit 10, one side end of the ice making container 12 to form ice is connected to the rotational force transmitter (16). The rotational force transmitter 16 rotates the ice maker 12 by rotating it by 180 ° to serve to transfer the ice formed in the ice maker 12 to the storage vessel 20 which will be described later. In addition, a temperature sensor 14 is installed at one side of the ice making container 12, which detects the temperature of the ice making container 12 and determines that ice is formed when the temperature is lower than a predetermined temperature to proceed with the subsequent stroke. will be. In addition, a support 17 is installed at one side of the rotational force transmitter 16, and an ice detection lever 18 that is movable up and down is supported by the support 17. The detection lever 18 is configured to enable a straight reciprocating motion up and down the support by the transmitted power, the operation of the detection lever 18 is made under the control of the microcomputer.

That is, the detection lever 18 determines whether the ice stored in the inside of the storage container 20 is ice by performing a linear movement up and down using the support 17 as the movement axis, and at the same time, the storage container 20 It plays a dual role in judging the existence of). Looking at the structure of the detection lever 18, the sliding shaft (18a) is connected to the support 17 and moved up and down, extending vertically downward from the end of the sliding shaft (18a) of the storage container portion 20 It consists of a vertical arm (18b) for detecting the presence, and a horizontal arm (18c) for branching from one side of the vertical arm (18b) and detects whether the ice in the storage container 20 is ice. The detection lever 18 is configured such that the horizontal arm 18c is located below the end of the vertical arm 18b.

Therefore, when the detection lever 18 is moved downward by a predetermined distance (d), the horizontal arm (18c) is located above the inside of the storage container 20, so that the ice stored in the storage container (20) You can detect the presence. In addition, when the detecting lever 18 is further moved downward by a predetermined distance D, the end of the vertical arm 18b contacts and stores the protrusions 22 formed on both side walls of the storage container 20. The presence of the container portion 20 can be detected.

That is, the sensing lever 18 first determines whether ice in the storage container 20 is full of ice, and the sensing arm 18 is moved downward by a predetermined distance d to the horizontal arm 18c. When the ice stored in the inside of the storage container 20 to the bottom of the contact is determined to be full ice. If it is determined that the ice is not in the above judgment, the projections 22 formed at the upper end of both side walls of the storage vessel 20 at the end of the vertical arm 18b are moved downward and moved by the total distance D. When contacted, it is determined that the storage container 20 is present, but not full ice, and the above-described rotational force transmitter 16 operates to perform the ice-breaking operation. However, if there is no contact of the storage container portion 20 at the end of the vertical arm (18b), it is determined that there is no storage container portion 20 is to play a dual role to prevent the icebreaking stroke is performed thereafter.

The linear motion of the ice detection lever 18 and the rotational motion of the ice making container 12 are all performed by the rotational force transmitter 16 under the control of the microcomputer. That is, by the power transmitted from the rotational force transmitter 16, the ice detection lever 18 performs a linear reciprocating motion along the up and down of the support 17, and the ice making container 14 performs a rotational motion. Since the control of the rotational and linear motion is generally known to those skilled in the art, a detailed description thereof will be omitted.

And, although not shown, if it is determined that there is no storage container 20 by the operation of the inspection lever 18, an alarm means (not shown) for notifying the user is installed therein. The alarm means may be configured in various ways, but in the present invention, it is configured to notify the user by using a buzzer sound. That is, when it is determined that the storage container unit 20 does not exist by the sensing lever 18, the buzzer sounds and the user can be notified. By the alarm sound, the user installs the storage container unit 20 when necessary. Done.

On the other hand, the linear motion of the ice detection lever 18 and the rotational motion of the ice-making container 14 by the transmission power of the rotational force transmitter 16 according to the temperature sensing of the temperature sensor 14 and the sensed temperature described above. Is configured to be adjusted by a microcomputer (not shown) installed therein. That is, the program according to each operation is input to the microcomputer in advance, the whole process, the ice making process of the ice making container 12, the temperature sensing of the temperature sensor 14, the ice making process by the operation of the ice detection lever 18. And the ice transfer process to the storage container unit 20 by the rotational motion of the ice-making container 14, the algorithm according to this series of processes are to proceed sequentially under the control of the microcomputer. And the control method of the microcomputer by such a series of algorithms are widely applied in the refrigerator currently on the market, and anyone skilled in the art can understand the detailed description of the microcomputer control.

Next, the storage container unit 20 according to the present invention will be described. The storage container 20 is positioned below the ice making unit 10 to store the ice formed in the ice making container 12. Looking at the structure of the storage container 20, the upper end of both side walls of the storage container 20 is bent in a horizontal length of a predetermined interval in the inward direction, and then again extended by a predetermined vertically upward direction 22 Has formed a structure.

The protrusion 22 is in contact with the vertical arm 18b of the above-described detection lever 18 to indicate the existence of the storage container 20. That is, the storage container 20 is installed such that the protrusion 22 of the storage container 20 is located vertically below the vertical arm 18b of the detection lever 18, and the detection lever 18 is provided. When is moved downward by a predetermined distance (D), the end of the vertical arm (18b) is in contact with the protrusion 22 of the reservoir 20.

Accordingly, the detection lever 18 determines whether the storage container part 20 is full by the operation of the predetermined distance d to the bottom, and again the operation of the storage container part 20 by the operation of the predetermined distance D. It can perform two functions to recognize existence.

On the other hand, the present invention, when the storage container 20 is not determined by determining the existence of the storage container 20, there is a feature to prevent the ice sheet operation is performed, so the existence of the storage container 20 The structure of the ice maker A for determining whether or not may be configured differently from the above. That is, the structure of the ice maker A may be configured in the same manner as in the related art, and may be configured to be performed by the sensing means by mounting a separate sensing means for sensing the existence of the storage container part 20. Therefore, in this case, it is possible to first determine whether or not by the conventional ice detection lever, and then to detect the existence of the storage container unit 20 by a separately installed sensing means, or first, the storage container unit by the sensing means After performing the detection of (20), it may be configured to detect whether the ice level by the detection lever.

As described above, in order to determine the existence of the storage container portion 20, which is a feature of the present invention, it may be configured in various ways, and it is understood that the present invention is not limited to the method of the detection lever 18 described above.

Next, an operation process of the ice maker by the control method of the refrigerator ice maker according to the present invention configured as described above will be described with reference to FIG. In the following description, the same components as in the prior art will be described using conventional symbols used in FIG. 1.

First, while the ice maker A is operated, the water delivered from the external fire source under the control of the microcomputer for ice making is supplied to the ice making container 12 through the water supply valve 7 (step 100). When the water supply is made for a predetermined time (step 110), the ice making unit 10 is operated to perform an ice making stroke. The ice making operation is performed for a predetermined time, and the time will be counted by the microcomputer (step 120).

After a predetermined time for making the ice making operation, the temperature sensor 14 detects the temperature of the ice making container 12 (step 130). This is to determine whether the ice making is completed as a temperature since the completion time of ice making varies depending on the temperature of the water to be supplied and the state of the inside of the refrigerator even if the ice making operation is performed for a predetermined time.

That is, if the temperature of the ice making container 12 sensed by the temperature sensor 14 is equal to or higher than the set temperature, it is determined that ice making is not performed, and the ice making stroke proceeds for a predetermined time, and the detected temperature is set to the set temperature. If it is below, it is determined that ice making is completed and the subsequent stroke is performed. Of course, the above-described process is input to the microcomputer as a series of algorithms, so the microcomputer will be controlled under the control of the microcomputer.

Next, when it is determined that ice making is performed in the above-described process, a subsequent process for transferring the ice formed in the ice making container 12 to the storage container part 20 is performed. That is, the operation of the ice detection lever 18 is performed. By the determination whether the ice stored in the interior of the storage container 20 is full ice, and if not the ice storage container 20 is determined.

For the above determination, by the power transmitted from the rotational force transmitter 16, the detection lever 18 moves downward along the support 17 by a predetermined distance d to determine whether it is full ice. Step 140), that is, when the detection lever 18 is moved by the above-mentioned distance d, the horizontal arm 18c of the detection lever 18 is located above the inside of the storage container 20. . Therefore, when the ice is filled with ice inside the storage container 20, the bottom surface of the horizontal arm 18c touches the ice stored in the storage container 20 so that the microcomputer can recognize it. . At this time, if it is determined that the ice is full, the storage container 20 is naturally determined to be installed, and subsequent steps are repeated at predetermined time intervals without a subsequent stroke.

On the other hand, if there is no ice in contact with the horizontal arm (18c) in the above-described process by the operation of the ice detection lever 18, it is determined that the ice is not full, conventionally, the ice making container 12 in accordance with the power transfer of the rotational force transmitter (16). Ice ice formed in the) is transferred to the storage container unit 20. However, in the present invention, when not in full ice, the presence of the storage container 20 is detected (step 150). That is, the detection lever 18 is operated again to move further downward by the total distance (D). At this time, if the storage container 20 is installed, the end of the vertical arm (18b) of the detection lever 18 is moved to the storage container 20 as the detection lever 18 is moved by the distance (D). It is in contact with the protrusion 22 formed on the upper side wall of the. Therefore, in this case, the storage container 20 is present, but it is determined that it is not full ice and proceeds with the ice ice administration (step 180).

However, when the storage container portion 20 is not provided, the protrusion 22 of the storage container portion 20 does not come into contact with the end portion of the vertical arm 18b of the sensing lever 18. Therefore, in this case, it is determined that there is no storage container unit 20, the alarm means is activated to notify the user instead of performing the icing operation (step 160), the user according to the operation of the buzzer sound storage container unit ( 20) (step 170). When the storage container unit 20 is mounted, the microcomputer recognizes this, stops the operation of the buzzer sound, and operates the sensing lever 18 again to proceed to the subsequent process.

In addition, when the storage container unit 20 exists by the operation of the above-mentioned ice detection lever 18, but the ice container is not full ice (operation 180). At this time, the rotational force transmitter 16 is operated under the control of the microcomputer so that the ice making machine 12 is rotated 180 ° so that the ice formed in the ice making machine 12 can be transferred to the storage container unit 20. As a result, the ice formed in the ice making container 12 is transferred into the storage container 20 to end one cycle. After the above process is completed, the process of supplying water into the ice making container 12 by the operation of the water supply valve 7 is repeated.

As described above, according to the ice detection lever structure and the control method of the ice maker according to the present invention, it is detected whether or not it is full ice and the presence or absence of the storage container part when it is not full ice. There is an effect that does not occur when it is poured.

Claims (5)

An ice making unit forming ice; An ice storage unit storing ice iced by the ice making unit; Ice detection means consisting of a lever that is moved up and down to detect whether the ice stored in the ice storage unit; And And a container detecting means formed integrally with the ice detecting means and determining whether the ice storage part is present by being in contact with the ice storage part. The method of claim 1, The ice-covering means, the structure of the refrigerator ice maker, characterized in that consisting of a horizontal arm of the lever is moved to a lower predetermined distance and in contact with the ice stored in the upper portion of the ice storage. The method of claim 1, The container detecting means, the structure of the refrigerator ice maker, characterized in that consisting of a vertical arm of the lever which is moved to a lower portion than the moving distance of the ice sensing means to contact the ice storage. A refrigerator provided with an ice maker, Ice formation step of forming ice in the ice maker; After ice is formed, the ice making step of determining whether the ice storage unit is full of ice by contacting the ice stored in the ice storage unit by moving the horizontal arm of the lever that is moved up and down a predetermined distance; Judging whether or not the ice storage unit is in contact with the ice storage unit by moving the vertical arm of the lever integrally formed on the horizontal arm to the bottom when it is determined that the ice storage unit is not in the ice determination unit; And A method of controlling an ice maker for a refrigerator, characterized in that the ice storage unit performs an ice-making operation, and when the ice storage unit does not exist, an ice-making control step is performed so that the ice-making operation is not performed. The method of claim 4, wherein The control method of the ice maker for a refrigerator, characterized in that further comprising an alarm step notifying the user when the ice storage unit does not exist in the container judging step.