KR100520951B1 - Fan control method in ice maker having fan assembly - Google Patents

Abstract

The present invention relates to a fan control method of an ice maker with a fan assembly that can increase the life of the fan by suppressing unnecessary control of the fan in the ice maker provided with the fan assembly in order to maximize the amount of ice making. According to the present invention, the fan is operated only in the ice making operation, and the fan is re-operated after checking the ice, water supply, and full ice detection status while maintaining the fan stopped state before the ice is performed. Therefore, by operating the fan assembly only once per cycle to prevent unnecessary operation, the life of the fan is extended.

Description

Fan control method in ice maker with fan assembly

The present invention relates to an ice maker with a fan assembly, and more particularly, to a fan assembly that can increase the life of the fan by suppressing unnecessary fan control operations in the ice maker with the fan assembly in order to maximize the amount of ice making. It relates to a fan control method of the ice maker provided.

In household appliances such as refrigerators, ice makers for manufacturing ice are employed to provide ice to users. The ice maker supplies cold air, which is a relatively low temperature air inside the refrigerator, to a tray of the ice maker to make ice more quickly. An ice maker structure having such a configuration is shown in FIG. 1.

As shown therein, the ice making body 1 is provided with an ice making tray 3. The ice tray 3 is actually divided into a plurality of spaces in which ice is formed. Reference numeral 5 denotes an ice detection lever. One side of the ice making body (1) is provided with a driving unit (7) in which a drive motor for driving the ice making tray (3) and the ice detection lever.

The fan assembly 10 is detachably installed at the driving unit 7. The fan assembly 10 is forcibly supplying cold air toward the ice making tray 3 so that the ice is produced more quickly.

The configuration of the fan assembly 10 will be described in detail with reference to FIG. 2. The housing 12 constitutes the external appearance of the fan assembly 10. The fan housing 14 is installed inside the housing 12. The sirocco fan 16 is installed inside the fan housing 14. The sirocco fan 16 serves to allow cold air to flow to the ice making tray 3 side. The sirocco fan 16 is driven by a fan motor 15 installed at one side of the fan housing 14.

One side of the housing 12, the duct housing 17 is installed. One side of the duct housing 17 is formed with a suction port (18). The suction port 18 is a passage through which cool air inside the refrigerator is sucked into the housing 12 by the sirocco fan 16. One side of the duct housing 17 is provided with a discharge duct 19 integrally. The discharge port 20 is formed at the end of the discharge duct 19 to be opened toward the lower portion of the ice making tray 3. The cold air conveyed by the sirocco fan 16 is discharged through the discharge port 20.

On the other hand, the housing cover 22 is provided to form one side of the housing 12, more specifically, the opposite side of the ice making body (1). The housing cover 22 forms an outer surface of the fan assembly 10.

Operation of the fan in the ice maker with the conventional fan assembly having the configuration as described above was made as follows.

3 is an operation flowchart for controlling the operation of the fan in the ice maker with the conventional fan assembly.

The fan 16 is operated only when the ice maker is operated. This is because the fan 16 is driven to quickly adjust the ice making time after the water is supplied to the ice maker. Therefore, there is no need to drive the fan 16 while the ice maker is not operating.

First, water is supplied to the ice making tray 3 (100th step). In the 100th step, water is supplied to the ice making tray 3 by driving the water supply valve for a predetermined time period in the controller.

When the water supply operation of the 100th step is completed, the controller applies a driving signal to supply power to the fan motor 15 (step 103). The fan motor 15 is driven by the operation signal at this time, the power for the rotation of the fan 16 is generated.

The rotation operation of the fan 16 according to step 103 is performed until the water supplied to the ice making tray 3 is completely converted into ice and ice making is completed. Therefore, the control unit detects the temperature of the ice making tray 3 through the temperature detecting unit for detecting the temperature of the ice making container, and continuously controls the fan 16 to the driving state until the detected temperature reaches a predetermined value.

When the temperature detected by the temperature detector is equal to a predetermined value according to the ice making completion point (x), the controller controls the ice-making operation (step 109). Prior to this, the controller cuts power supplied to the fan motor to output a control signal for stopping the rotation operation of the fan 16 (step 112). The power for the rotation of the fan 16 is cut off while the power supplied to the fan motor 15 is cut by the control of the step 112.

The controller 320 outputs a signal to a motor provided in the driver 7 to generate power for the ice. The ice power is transmitted to an ice lever located above the ice tray 3 to ice the ice ice from the ice tray 3 while rotating the ice lever. The iced ice is stored in the ice storage container located at the bottom of the ice tray.

When the ice-making operation is completed, the controller resumes rotation of the fan 16 again. That is, the fan motor 15 is driven by controlling power to be supplied to the fan motor again. In this way, the fan 16 starts to rotate again (step 115).

On the other hand, the controller performs a process of determining the amount of ice stored in the ice storage container in order to determine whether to re-ice ice after performing the ice removal operation according to the step 109. This operation also generates power for the ice detection operation in the motor inside the drive unit 7.

As the ice detection lever 5 is rotated by the generated power as described above, it is determined whether the amount of ice stored in the ice storage container is in an ice state (step 118). If the rotation range of the detection lever 5 is limited while ice is contacted during the rotation operation of the detection lever 5, the micro switch configured to be mechanically interlocked with the detection lever 5 is operated to allow the controller to be in contact with the ice. Generate a signal.

When the controller recognizes that the ice is in this manner, the controller no longer controls the ice making operation. In addition, a signal for cutting off power supplied to the fan motor is applied to block driving of the fan motor 15 (step 121). In the 121st step, the rotation of the fan 16 is also limited since the ice making operation is no longer performed.

However, in the step 118, when it is not in the full ice state, the control unit repeatedly performs the control according to the ice making operation and the ice making operation and the ice making operation.

An ice maker with a conventional fan assembly having such a control configuration has the following problems.

In the ice maker equipped with the conventional fan assembly, the fan is turned on / off twice in one cycle according to a water supply operation, an ice making operation, an ice making operation, and a full ice detection operation. That is, the on / off operation of the fan is performed once in the process of moving, and the on / off operation of the fan is performed once again after the ice detection and water supply process. Conventional ice makers made of this control operation generate unnecessary fan on / off operations while operating the fan twice in one cycle, which causes a problem of shortening the fan life.

Accordingly, an object of the present invention is to provide a fan control method in an ice maker having a fan assembly which can increase fan life by suppressing an on / off operation of an unnecessary fan.

The fan control method in the ice maker with a fan assembly according to the present invention for achieving the above object, the ice maker having a fan assembly for supplying cold air to the ice making tray, and automatically controls the ice making, ice, water supply, the ice detection operation. In the ice making operation, the fan drive step of controlling the cold air is supplied to the ice tray by driving the fan assembly; And a fan stop step of stopping the fan assembly before performing the ice moving operation, checking the ice, water supply, and full ice detection conditions, and then performing the fan driving step again.

In another embodiment of the present invention, there is provided an ice making machine including a fan assembly for supplying cold air to an ice making tray, comprising: a first step of operating a fan assembly; A second step of monitoring whether the ice making operation is completed while the fan assembly is in operation; A third step of stopping the fan assembly when the ice making operation is completed; A fourth step of performing an ice-making operation and a water supply operation after the fan assembly is stopped; After the water supply operation, performing the ice-covering operation, and if not in the ice state, returns to the first step to repeatedly perform the operations, and in the ice state, a fifth step of waiting for the ice to be released. .

Hereinafter, a fan control method in an ice maker with a fan assembly according to the present invention will be described in detail with reference to the accompanying drawings.

4 shows a perspective view of a preferred embodiment of an ice maker with a fan assembly according to the present invention, and FIG. 5 shows a partial sectional side view of the main components of the present invention.

As shown in these figures, the ice maker 30 of this embodiment is equipped with the ice making body 40. As shown in FIG. The ice making body 40 is provided with a body frame 41. Fixing hanger 41 ′ is integrally formed on the main body frame 41 to allow the ice maker 30 to be mounted on one side of the refrigerator. The body frame 41 is equipped with various components constituting the ice maker 30. To this end, one side of the main body frame 41 is provided with first and second mounting frame parts 42 and 43. A predetermined interval is provided between the first and second mounting frame parts 42 and 43, and various parts are provided therebetween.

An ice making tray 45 is rotatably installed in the main body frame 41. The ice tray 45 is a portion where ice is made. One end of the ice making tray 45 is connected to the driving motor 52, which will be described below, through the first mounting frame part 42 and rotated. Reference numeral 46 is an ice lever for discharging the ice of the ice tray 45 to a separate storage container, 48 is an ice detection lever for detecting the amount of ice in the storage container, and 50 is a tray cover.

Meanwhile, a driving motor 52 for operating the ice tray 45, the ice lever 46, the ice detection lever 48, and the like between the first mounting frame portion 42 and the second mounting frame portion 43. ) Is installed. Between the first mounting frame portion 42 and the second mounting frame portion 43, power of the driving motor 52 is transferred to the ice making tray 45, the ice lever 46, the ice detection lever 48, and the like. Parts, such as a gear, for transmission are provided. Reference numeral 54 is a control unit.

The fan assembly 60 is mounted on one side of the ice making body 40. The fan assembly 60 pumps cold air inside the refrigerator to the ice making tray 45 so that ice is formed more quickly.

The fan assembly 60 has a housing formed in its exterior, and the housing is formed by combining a first housing part 62a and a second housing part 62b. Partition plates 64 are provided inside the housing, respectively. The partition plate 64 is a flow path through which cold air flows by partitioning the interior of the first and second housing parts 62a and 62b by coupling the first and second housing parts 62a and 62b to each other. 64f). As shown in FIG. 4, the flow path 64f is formed such that the flow cross-sectional area becomes narrower from the upstream portion to the downstream portion.

A mounting rib 65 is formed on the partition plate 64 of the first housing part 62a. The mounting rib 65 is configured to mount the box fan unit 80. A mounting rib 65 ′ for mounting the box fan unit 80 is formed at an inner lower end of the second housing part 62b. The mounting ribs 65 and 65 'are formed at positions corresponding to the edges of the box fan unit 80 facing each other, and are formed in pairs so that both ends of the outer edge of the box fan unit 80 are inserted.

Discharge ducts 66 communicating with the flow path 64f are elongated in the first and second housing parts 62a and 62b. The discharge duct 66 is half formed in the first and second housing parts 62a and 62b, respectively, to form one flow path therein. A discharge port 68 is formed at the distal end of the discharge duct 66. The discharge duct 66 is formed to extend so that the discharge port 68 is in a position corresponding to the lower side of one side of the ice making tray 45. Here, the bottom surface of the cold air flow path 64f formed in the housing 62 and the bottom surface of the discharge duct 66 are formed in a plane without height difference, as shown in FIG. 4. And the end of the discharge duct 66 is formed to be inclined upward toward the lower surface of the ice making tray (45).

The housing 62 is formed to be open at both ends thereof, that is, at a position corresponding to the body frame 41 and the opposite side thereof. The housing cover 70 shields the opposite side of the main body frame 41. The housing cover 70 is formed with a suction port 72 for communicating with the flow path 64f and the outside.

The box fan unit 80 is installed inside the flow path 64f formed in the first and second housing parts 62a and 62b. The box fan unit 80 is installed with a corner seated on the mounting ribs 65 and 65 '. The box fan unit 80 is provided with a fan to provide a driving force for the flow of cold air through the flow path (64f). The box fan unit 80 is integrally provided with a motor unit for driving the fan. The motor unit used here is a DC motor using a DC power source. The motor unit is controlled by the control unit 54.

The ice maker 30 having the fan assembly 60 as described above is used to be mounted on one side of the refrigerator by the fixing hanger 41 ′. ) Is supplied with water, and ice is formed by cold air inside the refrigerator. At this time, the cold air inside the refrigerator is pumped by the fan assembly 60 and is supplied to the lower portion of the ice making tray 45.

That is, the box fan unit 80 is operated to supply cool air inside the refrigerator to the cold air flow path 64f through the suction port 72. The cold air sucked into the cold air flow path 64f passes through the box fan unit 80 and flows to the discharge duct 66. The cold air passing through the discharge duct 66 is supplied to the lower portion of the ice making tray 45 through the discharge port 68.

Next, a control configuration of the ice maker according to the present invention having the above configuration will be described with reference to FIG. 6.

The ice maker of the present invention is provided with a water supply valve driving unit 340 which is driven when water is supplied to the ice making tray 45 to make ice. The water supply valve driver 340 is driven to supply water to the ice making tray 45 during the water supply time monitored by the controller 54.

After the water is supplied to the ice making tray 45, a fan motor driving unit 330 is provided to drive a fan for forcibly supplying cold air toward the ice making tray 45 so as to quickly make the ice making operation. The fan motor driver 330 drives the fan under the control of the controller 320. The fan motor driver 330 is configured to supply power to the fan motor inside the box fan unit 80.

 In addition, the ice maker of the present invention is provided on one side of the ice making tray 45, and is provided with a temperature detection unit 300 for detecting a temperature which is a basic signal for determining whether ice making. The temperature detected by the temperature detector 300 is transmitted to the controller 54. The controller 54 monitors whether the detection signal of the temperature detector 300 reaches a predetermined value (a value set for determining an ice making completion point), and performs control according to an ice making operation by the ice making completion determination. Done.

In addition, a micro switch 310 configured to operate on / off in association with an operation state of the sensing lever 48 is provided, and an operation signal of the micro switch 310 is input to the controller 54. The controller 54 receives the signal of the micro switch 310 and determines that iced ice has been iced.

Reference numeral 350 is a motor drive unit. The motor driving unit is configured to provide power required for the operation of the ice lever 46 and the ice detection lever 48 to ice the iced ice from the tray 45. The motor driving part 350 is configured to open and close the power supply to the drive motor 52.

In addition, a lower end of the ice making tray 45 is provided with a heater 90 which is driven to separate the ice making ice from the tray during the ice making operation. The heater 90 is driven by the heater driver 360 under the control of the controller 54.

Next, a process of controlling the operation of the fan in the ice maker according to the present invention having the above configuration will be described.

7 is an operation flowchart for controlling the fan in the ice maker according to the present invention.

In the ice maker of the present invention, the water supply operation, the ice making operation, the ice making operation, the ice detection operation, and the like are all controlled to perform the fan on / off operation only once during one cycle. In the ice maker of the present invention, the fan is operated only while the ice making operation is being performed.

In a state in which water is supplied to the ice making tray 45, the controller 54 applies a signal for driving the fan motor inside the box fan unit 80 to the fan motor driver 330 (S220). By controlling the 220th step, the fan motor driving unit 330 allows power to be supplied to the fan motor, and thus the fan motor inside the box fan unit 80 starts to be driven.

When the fan motor starts to be driven, cold air inside the refrigerator is supplied to the cold air flow path 64f through the suction port 72. The cold air sucked into the cold air flow path 64f passes through the box fan unit 80 and flows to the discharge duct 66. The cold air passing through the discharge duct 66 is supplied to the lower portion of the ice making tray 45 through the discharge port 68.

In this way, while the cold air is rapidly supplied to the ice making tray 45, the water contained in the ice making tray 45 is iced. On the other hand, the control unit 320 monitors the detection temperature through the temperature detector 300 while controlling the drive of the box fan unit 80.

The temperature detection unit 300 is provided on one side of the ice making tray 45 to detect the temperature of the ice making tray 45. This operates to monitor whether the water contained in the ice making tray 45 is completely frozen. That is, when the water contained in the ice making tray 45 is frozen, the temperature of the ice making tray falls below a predetermined temperature (x). Therefore, the controller 54 checks whether the temperature sensed by the temperature detector 300 falls below a predetermined temperature (x) (step 203).

If the condition of step 203 is satisfied, the controller 54 determines that ice making is completed. Therefore, we no longer need to supply cold air. Therefore, the controller 54 controls the driving of the box fan unit 80 to the stopped state through the fan motor driver 330 (step 206).

After stopping the box fan unit 80 in step 206, the controller 54 controls an operation of ice-icing the ice on the ice making tray 45 (step 209). First, the control unit 54 supplies power to the heater 90 through the heater driving unit 360 and drives the heater. Since the heater 90 is in a state where the ice making tray 45 and the ice making ice are stuck due to the ice making operation, the heater 90 is operated to slightly melt the lower end of the ice making ice.

The control unit 54 drives the driving motor 52 through the motor driving unit 350. The drive motor 52 generates a rotational force for rotating the ice lever 46. The ice lever 46 rotates by the rotational force generated by the motor 52 and pushes the ice making ice of the ice making tray 45 to the outside of the ice making tray 45.

When the ice removal operation of step 209 is completed, the controller 54 supplies water to the ice making tray 45 by operating the water supply valve through the water supply valve driver 340 (step 212). Then, it is determined whether the amount of ice iced through the ice detection lever is in the ice state (Step 215). Steps 212 and 215 are performed at about the same time.

When the amount of ice already iced in the step 215 is in the ice state, no further ice making operation is performed. That is, a container for storing ice at the bottom of the ice making tray 45 is provided separately, and the ice state is a state in which the amount of ice stored in the container is full. Therefore, when the ice state is being detected, if more ice is iced, the container to be stored is insufficient.

Accordingly, the step 215 is a standby state in which no operation among the ice making, ice-making, and water supply operations is performed until the ice is released from the above-mentioned full ice state. When the user removes the ice and releases it from the full ice state, the control unit 54 returns to step 200 again to repeat the above operations.

At this time, since the water is supplied to the ice tray 45 at step 212, the ice making operation is performed while the box fan unit 80 is driven again, and the ice making operation is performed when the ice making operation is completed.

As described above, in the present invention, the box fan unit 80 is turned on / off only once during one cycle in which ice making, ice-making, watering, and ice-covering are all performed once. In particular, the box fan unit 80 is operated only during the deicing operation, thereby preventing the box fan unit 80 from being unnecessarily operated in other operations. Therefore, the present invention reduces the unnecessary operation by operating the fan assembly only once per cycle.

In the embodiment of the present invention, the first operation of the ice maker requires an operation of directly supplying water to the ice making tray 45. This is because in the present invention, the water supply operation is configured to be performed after the ice making operation and the ice making operation. However, after the one ice making operation and the ice making operation are performed, the water supply operation according to step 212 is automatically performed.

The fan control method of the ice maker with the fan assembly according to the present invention described above, the fan is operated only in the ice making operation, while the fan is stopped and maintained while the ice is stopped before the ice-making operation is carried out. After checking, it is determined whether the fan is to be re-operated. Therefore, by operating the fan assembly only once per cycle to prevent unnecessary operation, the life of the fan is extended.

1 is a side view showing the configuration of an ice maker with a fan assembly according to the prior art.

2 is a control block diagram of an ice maker according to the prior art.

3 is an operation flowchart for controlling the fan in the ice maker according to the prior art.

Figure 4 is a perspective view of the appearance of a preferred embodiment of an ice maker with a fan assembly according to the present invention.

Figure 5 is a partial cross-sectional side view of the main portion of the embodiment of the present invention.

Figure 6 is a control block diagram of an ice maker with a fan assembly according to the present invention.

7 is an operation flowchart for controlling the fan in the ice maker according to the present invention.

Explanation of symbols on the main parts of the drawings

30: ice maker 40: ice maker

45: ice tray 46: ice lever

52: drive motor 54: control unit

60: fan assembly 62: housing

65,65 ': Mounting rib 66: Exhaust duct

68: discharge port 70: housing cover

72: suction port 74: tightening rib

76: jam rib 80: box fan unit

300: temperature detector 310: micro switch

330: fan motor drive unit 340: water supply valve drive unit

350: motor driving unit 360: heater driving unit

Claims (2)

In the ice maker which is equipped with the fan assembly which supplies cold air to an ice making tray, and automatically controls ice-making, ice-making, water supply, and ice-covering motion, A fan driving step of controlling the cold air to be supplied to the ice making tray by driving the fan assembly during the ice making operation; A fan control method for an ice maker with a fan assembly, comprising: a fan stopping step of stopping the fan assembly before performing the ice-moving operation and re-performing the fan driving step after checking the ice, water supply, and full ice detection conditions. In an ice maker with a fan assembly for supplying cold air to the ice tray, A first step of operating the fan assembly; A second step of monitoring whether the ice making operation is completed while the fan assembly is in operation; A third step of stopping the fan assembly when the ice making operation is completed; A fourth step of performing an ice-making operation and a water supply operation after the fan assembly is stopped; After the water supply operation, performing the ice-covering operation, and when not in the ice state, it returns to the first step to repeat the operations, and in the ice state comprises a fifth step of waiting until the ice is released Fan control method of an ice maker provided with a fan assembly.