KR20030021528A - apparatus for heater control of ice maker for refrigerator - Google Patents

Abstract

PURPOSE: An apparatus for controlling a heater of an ice making machine for a refrigerator is provided to minimize influence of surrounding environment. CONSTITUTION: An apparatus includes a plate(52) having at least one groove(62,63) formed at regular intervals and installed on a rotary axis(54) of a motor(56) to rotate together with an ice ejecting lever(14); an optical sensor detecting turning amount of the ice ejecting lever through the grooves formed on the plate; and a control part(58) turning off a heater generating heat to eject manufactured ice from an ice making bin when the optical sensor detects signal twice through the grooves formed on the plate.

Description

Apparatus for heater control of ice maker for refrigerator}

The present invention relates to a heater control device of a refrigerator ice maker, and more particularly, to a heater of a refrigerator ice maker that controls the operation of the heater appropriately during the ice making operation of the ice maker installed inside the freezer compartment so that the normal ice making operation can be performed. It relates to an interruption device.

1 and 2 illustrate a configuration of a conventional ice maker, and with reference to this, a configuration of a general ice maker will be described.

The ice maker as shown in the figure is fixed to the wall surface of the freezer using the connection brackets 2a and 2b extending upward from the ice maker 12, for example, the holes formed in the connection brackets 2a and 2b. It is fixed to the wall surface of the freezer compartment using a fastening screw.

The ice maker 12, which contains water for ice making and makes ice of a predetermined shape, has a cross section shaped into a half moon shape and is formed of a material having excellent thermal conductivity, for example, aluminum. The water supply to the ice making container 12 is made through a feed tube connection part 4 formed at one side.

An ice lever 14 is installed at an upper portion of the ice making container 12. The ice lever 14 is configured to rotate to take out ice completely defrosted from the ice making container 12 to the outside of the ice making container by using the rotational force of the driving motor installed inside the casing 20. have.

And as can be seen in Figure 1b, a heater 15 for applying a small amount of heat so that the completed ice is separated from the ice making container 12 is installed in the lower portion of the ice making container 12. Therefore, when cold air is supplied for a predetermined time and the ice making is completed, the heater 15 generates heat to space the ice attached to the ice making container 12. The semi-moon-shaped ice spaced in this way is separated from the ice making container 12 by the rotation of the ice lever 14. And the ice is separated in this way, fall into the ice storage container (not shown) located below. In order to prevent the ice separated at this time from entering the inside of the ice making container 12 again, a stripper 6 is provided on the front upper surface of the ice making container 12.

And before the ice is separated from the ice making container 12, whether or not the ice is filled in the ice storage container at the bottom is detected by the ice detection lever (16). The detection lever 16 is moved up and down within a predetermined angle range by a motor in the casing 20, and detects whether the ice storage container in the lower portion is full of ice.

The stripper 6 extends to the rear side from the front plate 18 and has a plurality of branch shapes. In addition, the above-mentioned moving lever 14 is designed to rotate between each stripper 6. The front plate 18 formed on the front surface of the ice making container 12 has a shape that extends downwardly from a height at which the ice making container 12 is located. This front plate 18 is for preventing the ice collected in the ice storage container substantially below it from contacting the ice making container 12. That is, when the ice accumulated in the ice storage container positioned below the ice making container 12 comes into contact with the ice making container 12, the ice may stick or the heater 15 installed below the ice making container 12 during the ice making process. It is melted by heat, and the melted water is frozen again after the heater is turned off, and the whole ice sticks or gets tangled. In order to prevent this, the front plate 18 is formed in a flat plate shape which extends to have a predetermined length vertically downward from the ice making container 12.

Here, the ice maker itself is as described above that is installed in the freezer compartment of the refrigerator. And by the cold air supplied into the freezer compartment, the water inside the ice making container 12 is made of ice.

Therefore, when cold air is supplied in the direction of the arrow in the freezer compartment, such cold air lowers the ice making container 12 by contacting the ice making container 12 through the rear of the front plate 18, and the ice making is performed. Will be done.

And heat is generated in the heater 15 during the ice. In the normal operation state of the heater 15, the heater 15 generates heat for a predetermined time and the heat generation should be stopped after a predetermined time when the ice in the ice making container 12 is iced. However, if the heater 15 is not in a normal state, heat generation may be continued. If this heat generation continues, a fatal adverse effect on the freezer performance of the refrigerator may be caused.

The ice-making operation of the conventional ice maker configured as described above is performed by sensing the temperature of the ice maker 12. Although not shown, the apparatus includes a temperature sensing element for sensing a temperature of the ice making container 12, and after sensing that ice making is completed according to the sensing temperature of the temperature sensing element, an ice-making operation by controlling the heating of the heater. To control.

However, since the temperature sensing device is generally affected by the surrounding environment, an error in the sensing temperature is frequently generated due to the change of the surrounding environment. For example, when cold air is supplied to the freezer by operating conditions of the refrigerator and when it is not, when the fan is operating or not, and when the freezer door is opened and closed by the user, Changes in the environment directly affect the sensing temperature of the temperature sensing element.

In general, in the process of detecting the completion of ice making and operating the heater to perform the ice making operation, since the time required for ice making is more than a predetermined time (about 1 hour), the temperature of the sensing element of the temperature sensing element is affected by the surrounding environment. Even if an error occurs, the operation start of the heater for the ice moving operation is delayed and does not adversely affect the freezer compartment.

However, in the process of sensing the completion of the ice-breaking operation and turning off the heater to complete the ice-breaking operation, since the time required for the ice-breaking operation (about 3 minutes) is very short, the error of the sensing temperature is very large. For example, if the heater is turned off too quickly, the ice-making operation may not proceed normally. On the contrary, if the heater is turned off too late, the heat generated by the heater may reach the freezer compartment and adversely affect other foods in storage.

This problem is because, in the conventional ice maker, the operation control of the heater according to the ice-making operation is based on the sensing temperature of the temperature sensing element for sensing the temperature of the ice maker 12. That is, the change of the surrounding environment affects the sensed temperature of the temperature sensing device and causes a problem of not accurately controlling the operation of the heater.

Accordingly, an object of the present invention is to provide a heater control device of a refrigerator ice maker that can physically detect a time when ice leaves the ice maker and efficiently control the operation of the heater.

1, 2 is a configuration diagram of a general ice maker,

3a and 3b is a configuration diagram for the heater control of the refrigerator ice maker according to the present invention,

4 is a heater control flow chart of the refrigerator ice maker according to the present invention.

Explanation of symbols on the main parts of the drawings

14: moving lever 52: plate

54: shaft 56: motor

58 control unit 60 light emitting unit

62,63: Home 64: Receiver

59: heater driving unit

The heater control device of the refrigerator ice maker according to the present invention for achieving the above object is an ice making container receiving water for forming ice; A heater installed under the ice making container and generating heat to separate the completed ice from the ice making container; An ice lever that rotates to extract the ice separated from the ice making container to the outside of the ice making container by driving the heater; 1. An ice machine for a refrigerator having a motor for providing a rotational force of the ice lever, comprising: a plate for forming one or more grooves at a predetermined interval and installed on a rotation shaft of the motor to rotate together with the rotation of the ice lever; An optical sensor for detecting an amount of rotation of the moving lever through a groove formed in the plate; And a control means for performing a control to turn off the operation of the heater when detecting the second signal from the optical sensor through the groove formed in the plate.

The optical sensor of the present invention is characterized in that a light emitting portion and a light receiving portion are provided facing the groove formed in the plate.

In the present invention, the spacing of the grooves formed on the plate is characterized in that it is adjusted to the time when the ice is extracted to the outside of the ice making vessel from the initial position of the ice lever.

Hereinafter, a heater control device of a refrigerator ice maker according to the present invention will be described in detail with reference to the accompanying drawings.

3A and 3B show the configuration of the heater interruption in the ice maker of the present invention in detail. In the present invention, the configuration of the ice maker will be described with reference to FIGS. 1 and 2. 3A are installed in the casing 20 except for the moving lever 14.

In addition, the interruption of the heater 15 to be described in the present invention is performed at the time of the ice moving operation. That is, the start of the operation of the heater 15 means the start of the ice-making operation, and the stop of the operation of the heater 15 means the completion of the ice-making operation. Therefore, the on / off control of the heater 15 in the present invention will be described in conjunction with the mechanical configuration of the ice-making operation.

As shown, in the present invention, an optical sensor is used for the on / off control of the heater. The optical sensor includes a light emitting unit 60 for emitting light when power is supplied, and a light receiving unit 64 for receiving light emitted from the light emitting unit 60. The light emitting unit 60 and the light receiving unit 64 are mounted to face each other based on the plate 52 to be described later, and the light receiving unit 64 is provided with grooves 62 and 63 formed in the plate 52. The light emitted from the light emitting unit 60 is received through.

The power supply to the light emitting unit 60 is configured to be controlled by the control unit 58 through the power line L2, and the signal received by the light receiving unit 64 is controlled by the control unit 58 through the signal line L3. Is configured to be entered. Accordingly, the controller 58 controls the on / off operation of the heater by inputting a signal of an optical sensor including the light emitting unit 60 and the light receiving unit 64.

In addition, the plate 52 is connected to the motor 56 and the rotating shaft 54 to provide a rotational force to the moving lever 14. Therefore, when the motor 56 rotates, the plate 52 and the moving lever 14 are rotated together. The grooves 62 and 63 are formed in the plate 52 as described above. The grooves 62 and 63 are formed at positions where light emitted from the light emitter 60 can be received by the light receiver 64.

3B is a front view of the plate 52, and the plate 52 is connected to the grooves 62 and 63 for detecting the light emitting unit 60, and the rotating shaft of the moving lever 14. The axis 54 to be made is shown.

In the present invention, the first groove 62 should be formed on the portion where the initial position detection of the ice lever can be made. In addition, the second groove 63 of the present invention physically marks the time point at which the ice pushed out of the ice making container 12 by the ice lever 14 rotated in accordance with the rotation of the motor 56 leaves the ice making container 12. It is formed on the detectable part. Therefore, after the light receiving unit receives the signal through the first groove 62 and reaches a point in time when the signal is received through the second groove 63 again after a predetermined time elapses, it is determined that the ice-making operation is completed.

In the present invention, the first groove 62 for detecting the initial position of the ice lever is not included in the range of the internal space in which the ice lever 14 is formed by the ice making container 12, and is illustrated in FIG. 1. As such, it means an arbitrary position on the top of the ice making container 12. Therefore, it is not necessary to limit the groove 62 for the initial position detection of the moving lever 14 to the position shown in FIG. 3B. That is, as long as the position is not included in the space range formed by the ice making container 12, any position can be set as an initial position.

The distance between the first groove 62 and the second groove 63 should always be constant. This is because the second groove 63 should be able to be used for signal detection after a certain time has elapsed after detecting the optical signal through the first groove 62. That is, the second groove 63 should be set to the extent that it is possible to physically detect the time when the ice leaves the ice making container from the first groove 62 at all times. This means that the position change of the second groove 63 should be accompanied with the initial position change.

As such, the interval between the first groove 62 and the second groove 63 can be set to be constant because the motor 56 driven for the moving operation is always controlled to be constantly driven. That is, the time at which the moving lever 14 is rotated is always set constant.

In addition, the control unit 58 of the present invention controls the rotation of the motor 56 through the power line (L1). The controller 58 is configured to control an operation of supplying power to the heater 15 through the heater driver 59.

The following describes the operation process for the on / off control of the heater in the ice maker of the present invention having the above configuration.

4 is an operation flowchart for on / off control of the heater in the ice maker according to the present invention.

Water is supplied to the ice making container 12, and when a predetermined time elapses, the water supplied to the ice making container 12 is frozen while making ice making. And the start of the ice-making operation is made by sensing the temperature of the ice making container (12). Although not shown, it is provided with a temperature sensing element for sensing the temperature of the ice making container 12, and detects that ice making is completed according to the sensing temperature of the temperature sensing element.

When the completion of ice making is detected by this operation, the ice-making operation is started under the control of the controller 58.

First, the controller 58 supplies power to the heater 15 through the heater driver 59 to control the heat generation (step 200). The built-in timer is initialized to check the time (step 203).

By the heating operation of the heater 15, heat generated by the heater is transferred to the ice making container 12. Therefore, the lower end of the ice frozen in the ice making container 12 is melted by the heat of the heater, and the state becomes movable.

The control unit 58 monitors whether the time counted in step 203 reaches a predetermined time. The predetermined time is for giving a time for melting the lower end of the ice by the heat of the heater 15.

In addition, the controller 58 supplies power to the motor 56 to generate a rotational force for the rotation of the ice lever 14. The rotational force generated by the motor 56 is transmitted to the moving lever 14 through the shaft 54, and the rotation of the moving lever 14 is started (step 209). The controller 58 turns on the light emitting unit 60 (Step 212).

When the heat generation operation of the heater 15 and the rotation operation of the ice lever 14 by the operation up to step 209 are started, the ice stuck to the ice making container 12 is spaced apart by the heater 15 heat, The rotation of the lever 14 starts to be extracted to the outside of the ice making container 12. The light emitting unit 60 emits light when power is supplied.

On the other hand, the plate 52 rotates with the rotation of the motor 56, and the ice lever 14 rotates at the same time, and the ice is extracted to the outside of the ice making container. At this time, when the groove 62, the light emitting portion 60, and the light receiving portion 64 are formed in a straight line, the light receiving portion 64 is formed through the groove 62. The light irradiated at 60 is received. In operation 215, the detected signal is applied to the controller 58.

When the light receiving unit 64 receives the light in step 215, the moving lever 14 is positioned at an initial position. Thus, the moving lever 14 positioned at the initial position is rotated at a constant speed by receiving a rotational force by the continuous driving of the motor 56. At this time, the rotation speed of the ice lever 14 is always made at a constant level.

When the ice lever 14 is rotated, ice melted at the lower end by heat of the heater is gradually pushed out of the ice container 12 by the ice lever 14. When this process is performed for a predetermined time or more, and the preset time is elapsed according to the rotational speed of the motor 56 (step 218), the light receiving unit 64 emits light through the other groove 63. The light at 60 is received (step 221).

At this time, the ice is extracted by the ice lever 14 to the outside of the ice making container 12. That is, while the ice lever 14 rotates, the ice pushed out by the ice lever 14 continuously leaves the ice maker 12 and falls to the storage container located under the ice maker.

Therefore, the controller 58 cuts off the power supply of the motor 56 at the time point when the second signal is detected in step 221, stops the rotation of the ice lever 14, and also stops the heating operation of the heater 15. (Step 224). Then, the operation of the motor 56 is turned off to complete the ribbing operation (step 227).

When the ice removal operation according to the above process is completed, water is supplied to the ice making container 12 again to proceed with ice making.

As described above, the present invention considers the influence of the sensing temperature of the temperature sensing unit according to the operating conditions of the refrigerator according to the operation state of the fan, the opening state of the door, etc. Physically detecting the departure time, it characterized in that for controlling the off operation of the heater. Therefore, the present invention minimizes the influence of the surrounding environment, and in particular, it is possible to precisely control the operation time of the heater during the moving operation.

In the control process of the present invention, if the signal is not detected despite a certain amount of rotation of the motor, it detects that the normal rotation is not made due to the forced restraint of the ice lever. Therefore, in this case, it is possible to control the failure display or the ice and ice making operations not to be performed so that the user can know.

As described above, the heater control device of the refrigerator ice maker according to the present invention controls the on / off operation of the heater by using an optical sensor, and thus there is no unnecessary heat generation operation after the completion of ice, as in the prior art, an ice making container. It can prevent ice melts from melting inside. That is, the present invention has the advantage of preventing the possibility of malfunction due to the conventional temperature control in advance.

In addition, the present invention can prevent the change in the operating time of the heater according to the change of the surrounding environment, thereby obtaining the effect of preventing unnecessary heat generation to give to the freezer.

Claims (3)

An ice making container for making ice; A heater installed under the ice making container and generating heat to separate the completed ice from the ice making container; An ice lever that rotates to extract the ice separated from the ice making container to the outside of the ice making container by driving the heater; In the icemaker for a refrigerator having a motor for providing a rotational force of the ice lever: A plate which forms one or more grooves at predetermined intervals and is installed on a rotation shaft of the motor to rotate together with the rotation of the ice lever; An optical sensor for detecting an amount of rotation of the moving lever through a groove formed in the plate; And a control means for performing control to turn off the operation of the heater when the optical sensor detects two signals through the groove formed in the plate. The method of claim 1, The optical sensor is a heater control device of the icemaker for a refrigerator, characterized in that facing the groove formed in the plate, the light emitting portion and the light receiving portion is installed. The method of claim 2, The interval between the grooves formed in the plate, the heater control device of the icemaker for a refrigerator, characterized in that adjusted from the initial position of the ice lever to the time when the ice is extracted to the outside of the ice maker.