KR100775120B1 - Apparatus for controlling of lamp in refrigerator and method thereof - Google Patents

Abstract

A lamp control circuit for controlling a backlight of a dispenser of a refrigerator and an array of operation buttons located on a front panel and a control method thereof are provided. The lamp control circuit may include: a dispenser provided at the refrigerator door to extract water / ice inside the refrigerator to the outside by a movement of an operation lever installed in a recess of the dispenser located at the front of the refrigerator door; A recess lamp positioned in the recess area of the dispenser and connected to the recess lamp to illuminate the light having a brightness corresponding to an input of a power supply voltage, and a button lamp to illuminate the light around the operation button in parallel; ; A lamp driver supplying a power supply voltage corresponding to a driving control signal to the recess lamp and the button lamp; An illumination sensor for sensing an ambient brightness of the refrigerator; In response to an output of the illuminance sensor, a driving control signal for lighting the recess lamp to the lowest brightness is provided to the lamp driving unit, and in response to the operation of the operation lever, the recess lamp and the button lamp have a maximum brightness. And a control unit that changes the drive control signal so that the drive lamp is gradually lowered from the maximum brightness to the lowest brightness when the operation lever is returned.

Refrigerator Lamp, Dispenser Lamp, Ambient Light Sensor, Pyroelectric Sensor, Brightness Control

Description

Lamp control circuit of refrigerator and its control method {APPARATUS FOR CONTROLLING OF LAMP IN REFRIGERATOR AND METHOD THEREOF}

1 is an external perspective view of a refrigerator having a lamp shining a recess of a dispenser according to a preferred embodiment of the present invention.

Figure 2 is a front view showing the dispenser structure of the refrigerator according to a preferred embodiment of the present invention.

3 is a dispenser lamp and button backlight control circuit diagram of a refrigerator according to a preferred embodiment of the present invention.

4 is a lamp control flowchart of a refrigerator according to a preferred embodiment of the present invention.

5A to 5C are driving waveform diagrams of the lamp and the button lamp shown in FIG.

`` Explanation of symbols for main parts of drawings ''

10: refrigerator, 12: door,

14 dispenser, 16 recess portion

18: outlet, 20: operating lever

22: operation panel, 23: display unit,

24: operation button, 26: lamp assembly,

28 bracket, 30 lamp,

31: reflector, 32: light sensor,

34: lever switch, 36: lamp drive unit,

38: button lamp, 40: control unit,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lamp control circuit of a refrigerator, and more particularly, to a lamp control circuit for controlling a back light of a refrigerator dispenser and a function button array located at a front panel, and a control thereof. It is about a method.

Recently, the refrigerators are gradually increasing in size to meet the needs of consumers, and accordingly, the development of large-sized two-door (or side-by-side) refrigerators has been actively developed. Since the two-door refrigerator has a large capacity, if the refrigerator door is frequently opened to take out a small amount of ice or water, there is a problem in that the loss of cold air increases. In order to reduce such cold air loss, a two-door refrigerator is generally provided with a separate dispenser at the front of the door to remove ice or water without opening or closing the door.

As an example of a refrigerator equipped with such a dispenser, US Patent No. 4,851,662 (hereinafter referred to as “prior art document”) is provided with a dispenser on the front of the door, and the dispenser has an operating lever for controlling the supply of ice or water, and A lamp for illuminating an ice container or the like in the dark, and a light sensing switch for controlling the lighting of the lamp are provided.

"Refrigerator ice dispenser light having a light sensing switch" disclosed in the prior art document illuminates a recess area in which an ice container or the like is placed in the dispenser by applying a voltage to the lamp when the operation lever of the dispenser is operated, In the state where the operation lever is not in operation and the brightness of the surroundings is dark, the operation of the photosensitive switch is applied to the lamp by applying a voltage of 1/2 to illuminate the recess of the dispenser.

The prior art disclosed in the above prior art document merely controls the " on / off " control of the power supply voltage applied to the lamp which illuminates the recess of the dispenser when the dispense lever of the dispenser is operated, and the power applied to the lamp when the surroundings are dark. It is only disclosed that the dispenser is conveniently used in a dark place where the voltage level is 1/2 of the usual time.

Therefore, the prior art disclosed in the above prior art document only turns the lamp "on" while operating the operating lever of the dispenser to take out ice or cooling water from the outlet, and immediately turns the lamp "off" when the operating lever returns to its original position. It was not easy to use at night. That is, as soon as the user pushes the cup into the dispenser and receives water or ice, the lamp “offs” and the surroundings suddenly become dark as soon as the cup is removed from the actuating lever, causing the cup to shake during the removal of the cup from the recess of the dispenser, There was a problem such as dropping the cup.

Korean Patent Publication No. 10-0506904 (refrigerator) discloses a lamp control circuit for solving the above problems. The technique disclosed in the Patent Publication discloses that when the operation lever of the dispenser is operated, the lamp is turned on by applying a power supply voltage to the lamp, and the power supply voltage is applied to the lamp for a predetermined time so that the level of the power supply voltage is gradually decreased. Only the technical configuration of turning off the lamp by gradually darkening the surrounding brightness is disclosed.

However, the conventional technique disclosed in the above-mentioned patent publication is to drive the lamp when the operation lever of the dispenser is operated. When the surroundings of the refrigerator are very dark, the user cannot find the exact position of the dispenser of the refrigerator and use the refrigerator dispenser correctly. Was difficult.

Accordingly, an object of the present invention is to provide an apparatus and a control method for controlling a lamp of a refrigerator to have an optimal use brightness by adaptively controlling a lamp that emits light around an operation button of the refrigerator and a dispenser to the ambient brightness of the refrigerator.

Another object of the present invention is to automatically control the lighting of the lamps located in the operation button unit and the dispenser of the refrigerator when the user is detected in the vicinity of the refrigerator and adjust the brightness of the lamp to control the brightness of the lamp An apparatus for controlling and a method of controlling the same are provided.

An object of the present invention is to provide a lamp control apparatus for a refrigerator to turn off the illuminance of a lamp that shines light on the recess of the dispenser for a predetermined time from a maximum brightness for a predetermined time when the operation of the ice ejecting lever of the refrigerator dispenser is detected; It is to provide a control method.

Lamp control circuit of the refrigerator of the present invention for achieving the above object in the lamp control circuit of the refrigerator,
A dispenser provided in the refrigerator door to draw water / ice inside the refrigerator to the outside by the movement of various levers installed in the recess of the dispenser located at the front of the refrigerator door;
A recess lamp positioned in the recess area of the dispenser and illuminating light of brightness corresponding to an input of a power voltage to the recess area;
A lamp driver supplying a power supply voltage corresponding to a driving control signal to the recess lamp;
An illumination sensor detecting the ambient brightness of the refrigerator;
A biological sensor for detecting the presence or absence of living organisms around the refrigerator;
In response to an output of the illuminance sensor, a driving control signal for lighting the recess lamp to the lowest brightness is provided to the lamp driver, and the recess lamp is set to the maximum brightness in response to the detection of the living organism by the biometric sensor. And a control unit for changing the drive control signal and varying the drive control signal such that the recess lamp gradually lowers the illuminance from the maximum brightness to the lowest brightness when the operation lever is returned after operation. .

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The biological sensor may be a far-infrared sensor or a pyroelectric infrared sensor that detects heat emitted from a human body, etc., but it is described in the embodiment of the present invention to use a highly sensitive pyroelectric far-infrared sensor.

The refrigerator lamp control device may further include a button lamp positioned at a lower portion of the operation panel installed in the refrigerator for setting a temperature of the refrigerator and illuminating the operation panel with an illuminance corresponding to a power voltage output from the lamp driver.

It is preferable that a light guide plate is provided between the operation button of the operation panel and the button lamp to guide light emitted from the button lamp in a wide area.

The control unit changes the driving control signal provided to the lamp driving unit to be the maximum brightness of the button lamp when the operation button is operated, and when the operation button is released (release) the button lamp from the maximum brightness to the lowest brightness It is more preferable to vary the drive control signal so that the illuminance gradually decreases.

The recess lamp and the button lamp may be connected to the output node of the lamp driving unit in parallel to be driven simultaneously so that the recess lamp and the button lamp may be collectively turned on when the operation lever or the operation button is operated by the user.

The control unit may include a first driving mode for lighting a recess lamp and a button lamp with minimum brightness, a second driving mode for lighting the two lamps with maximum brightness, and a driving control signal input to the lamp driving unit; It is characterized in that the output to the third driving mode for varying the brightness from the maximum brightness to the minimum brightness within a certain time and the fourth driving mode to turn off the two lamps from the maximum brightness within a certain time.

In order to output the driving control signals of the first driving mode and the third and fourth driving modes as described above, the controller controls the duty ratio of "on" / "off" of the driving control signals output to the lamp driver. It is preferable to have a PWM (Pulse Width Modulation) in the interior of the control unit in order to control the output.

The on / off duty ratio of the first driving mode is set to 0% to 10% when the output period 1 / T is 5 msec corresponding to the ambient brightness of the refrigerator, and the on / off duty ratio of the third driving mode is set to 0% to 10%. Is set to gradually decrease from 90% to 10% when the output period is 5msec, and the on / off duty ratio of the fourth drive mode gradually decreases from 90% to 10% when the output period is 5msec. It is set to.

The illuminance sensor may be implemented using a light guide element using cadmium sulfide (Cds).

According to another aspect of the present invention, a refrigerator lamp control method includes a dispenser provided at a door of a refrigerator to blow out ice or water in a refrigerator to the outside by an operation of an operation lever, and a light to illuminate a recessed area of the dispenser. The present invention is very useful in a refrigerator having a set lamp, an operation button for controlling the operation of the refrigerator, and a button lamp positioned below the light emitting the operation button.

The method of controlling the refrigerator lamp includes driving a lamp that illuminates a recess area of the dispenser at the lowest brightness corresponding to the brightness of the refrigerator, in response to an operation lever provided on the dispenser, an operation button, or a user's proximity detection of the refrigerator. Driving the lamp at the maximum brightness, and controlling a brightness of the lamp so that the lit lamp gradually darkens to the minimum brightness for a preset time in response to the return of the operation lever or the operation button. Wherein, further comprising the step of retrieving the day and night status in response to the output of the illumination sensor for detecting the ambient brightness of the refrigerator; And a time for which the lit lamp is preset in response to the return of the operating lever. Not the gradually darkened to a minimum brightness to be characterized in that it further comprises controlling to turn off.

The lamp brightness adjustment process may gradually reduce the effective voltage of the power supply voltage input to the lamp.

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Although the present invention has been described in the case of determining the day and night by the output of the illumination sensor, by providing an automatic / manual (or day / night mode) switch set by the user, day and night (auto / manual) according to the setting of the switch Can be determined.

The present invention as described above is a recess lamp that senses the brightness of the surroundings of the refrigerator to the illumination sensor, and when the user operates the operation button for selecting the operation of the lever of the dispenser or the operation of the refrigerator to illuminate the recess area of the dispenser By turning on and off the button lamp and automatically adjusting the brightness of the lamp gradually within a certain time, the minimum brightness can be maintained or turned off, making it easier to use the refrigerator.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described in more detail with reference to the accompanying drawings in which: FIG. It should be understood, however, that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth. It should be noted that the embodiments of the present invention described below are merely for explaining the spirit of the present invention to those skilled in the art, and detailed descriptions of well-known functions and configurations in the art that may unnecessarily obscure the gist of the present invention are provided. Note that it is omitted.

1 is an external perspective view of a refrigerator having a lamp that illuminates a recess of a dispenser according to a preferred embodiment of the present invention, and FIG. 2 is a front view illustrating a dispenser structure of the refrigerator according to the preferred embodiment of the present invention.

First, the appearance structure of the refrigerator 10 according to an exemplary embodiment of the present invention will be briefly described with reference to FIGS. 1 and 2.

The refrigerator 10 according to the present invention has a storage compartment partitioned from side to side by an intermediate partition, as shown in FIG. 1, and the front and rear sides of the refrigerator 10 are hinged and coupled to open and close each storage compartment. The door 12 is provided, the storage compartment is partitioned by a plurality of shelves, the inside of the door 12 is provided with a plurality of door guards to accommodate a beverage bottle or can.

Like a conventional double door refrigerator, the left storage compartment of the refrigerator 10 is a freezer compartment, and the dispenser 14 has a front surface of the door 12 so that ice or water can be easily taken out without opening or closing the door 12. Is provided.

As shown in FIG. 2, the dispenser 14 is provided with a recessed portion 16 recessed rearward to accommodate an ice container, a water cup, or the like, and an ice above the recessed portion 16. A discharge port 18 through which water or water is provided is provided, and an operation lever 20 is provided at the rear of the recess 16 to pressurize by an ice container or the like to adjust the discharge of ice or water.

An upper side of the recess 16 is provided with a display unit 23 for displaying the operating state of the refrigerator and an operation panel 22 provided with an operation button 24 for controlling the operation of the refrigerator 10. A recess lamp 30 and a button lamp 38 for illuminating the recess 41 are provided at the rear of the operation panel 24, and between the operation button 24 and the button lamp 38. It is provided with a light guide plate for guiding the light emitted by the button lamp 38 as a whole. The light shining from the button lamp 38 and the recess lamp 30 illuminates the operation panel 24 placed in front of the button lamp 38 and the recess 16 located below. The button lamp 38 and the recess lamp 30 are connected to receive power applied through a wire.

In FIG. 2, reference numeral 26 denotes a lamp assembly, in which a lamp 30 is mounted to the bracket 28 and connected to the bracket 28, and a reflecting plate 31 capable of efficiently shining the light of the lamp 30 onto the recess 16. Shown in the figure.

In the exemplary embodiment of the present invention, in the exemplary embodiment of the present invention, an example in which the recess 16 and the operation button 24 are respectively illuminated by two lamps 30 and 38 is described. Only the recess lamp 30 illuminating the light may be illuminated by illuminating a light guide plate (not shown) positioned below the operation button 24.

3 is a circuit diagram illustrating a dispenser lamp and a button backlight of a refrigerator according to a preferred embodiment of the present invention.

3, the lamp control apparatus of the refrigerator 10 according to the present invention is switched in conjunction with the illumination sensor 32, the operating lever 20 in the dispenser 14 to detect the ambient brightness of the refrigerator 10. Lever switch 34, whether there is a living organism around the mode switch 35 and the refrigerator 10, which is turned on / off by the user and generates a user input signal corresponding to the automatic (night) / manual (weekly) setting state The biological sensor 39 to detect is provided. In the embodiment of the present invention, an example in which the pyroelectric far infrared sensor is used as the biological sensor 39 is created in the drawing.

The output terminal of the illuminance sensor 32 and the output terminal of the pyroelectric far-infrared sensor (hereinafter referred to as "pyroelectric sensor") 39 and one side of the lever switch 34, the mode switch 35 and the operation button ( The other side of 24 is connected to the input port of the controller 40.

The controller 40 is configured to output the illumination sensor 32, the pyroelectric sensor 39, the mode switch 35, the operation button 24, and the lever switch 34 by a lamp control module programmed in an internal mask area. The recessed lamp connected to the output node of the lamp driver 36 by reading the switching state and outputting a PWM pulse having a logic “high”, “low” or a predetermined duty ratio to the lamp driver 36 connected to the output port. 30 and the button lamp 38 are turned on and off, and the brightness is controlled.

The lamp driver 36 has a base connected to the collector of the switching transistor Q1 which is switched on / off according to the logic level of the drive control signal, thereby supplying the emitter power supply voltage Vcc to the recess lamp 30 and the button lamp. It consists of driver transistor Q2 for driving 38 and bias resistors R1 and R2. The lamp driver 36 configured as described above provides the driving voltages corresponding to the driving control signals applied to the base of the switching transistor Q1 to the two lamps 30 and 38.

For example, when the driving control signal input to the base of the switching transistor Q1 is input to the logic "high", both the transistor Q1 and the drive transistor Q2 are "turned on" and the recess lamp 30 One side of the button lamp 38 is supplied with a driving voltage "Vdc = Vcc-Vec" obtained by subtracting the voltage drop of the voltage Vec between the emitter and collector of the drive transistor Q2 from the power supply voltage Vcc and lighting it at the maximum brightness.

If the driving control signal in the form of a pulse having an on / off duty ratio of 50% is output from the controller 40, the switching transistor Q1 and the driver transistor Q2 correspond to the driving control signal of the pulse type. By "on / off" switching, the effective voltage provided to the recess lamp 30 and the button lamp 38 is reduced to about 1/2, so that the brightness is also darkened to 1/2. Therefore, it can be seen that the brightness of the lamps 30 and 38 is adjusted according to the increase or decrease in the duty ratio of the driving control signal applied from the controller 40 to the lamp driver 36.

FIG. 4 is a flowchart illustrating a lamp control of a refrigerator according to an exemplary embodiment of the present invention, which is programmed in the ROM region of the controller 40 of FIG. 3, and FIG. 5 is a driving waveform diagram of the lamp and the button lamp of FIG. 3.

1 to 5 will be described in detail the operation of the refrigerator lamp control according to the present invention.

When the lamp control apparatus shown in FIG. 3 is operated, the controller 40 searches for the switching state of the mode switch 35 in step S10 of FIG. Here, the automatic mode is controlled to the minimum brightness, the pyroelectric sensor 39 detects a person in the vicinity of the refrigerator 10, or the operation lever 20 of the dispenser 14 is operated by the user's action or the operation button. When 24 is selected, the brightness of the lamps 30 and 38 is controlled to the maximum, and when the operating lever 20 or the operation button 24 is returned, the two lamps 30 and 38 are returned to the minimum brightness again. It means to keep on lighting. By this control, the user can easily use the dispenser of the refrigerator 10 located in a dark place.

In the above, the control of the recess lamp 30 and the button lamp 38 to the minimum brightness means that the recess 16 and the operation button 24 of the dispenser 14 correspond to the ambient illumination, that is, the brightness. The illumination means that the sides can be recognized by the user, and the brightness of the surroundings of the refrigerator is very bright due to sunlight, and the recess lamp 30 and the button lamp 38 include a state of being turned off. shall.

The mode switch 35 as described above is set to an on or off state by the user.

When it is determined that the automatic mode in step S10 of FIG. 4, the control unit 40 detects the ambient brightness of the refrigerator 10 by reading the output of the illumination sensor 32 in step S12, and at the step S14, the lowest brightness corresponding to the ambient light level. The first driving mode signal for driving the low recess lamp 30 and the button lamp 38, that is, the lowest brightness driving control signal is output. For example, in step S14 of FIG. 4, the control unit 40 may have a pulse shape in which a duty ratio of turn on (T _ON ) and turn off (T _OFF ) of a pulse having a cycle of 5 msec is set to about 10% or less as shown in FIG. The driving control signal is provided to the lamp driver 36 to drive the recess lamp 30 and the button lamp 38 by a voltage equal to 1/10 of the power supply voltage VCC to maintain minimum brightness.

In the above process, the controller 40 which drives the brightness of the recess lamp 30 and the button lamp 38 connected in parallel to the minimum brightness is interlocked with the operation lever 20 of the dispenser 14 in step S16 of FIG. 4. By reading the switching state of the lever switch 34 or the operation button 24 is switched to search whether the operating lever 20 or the operation button 24 is operated.

If no signal is input as a result of the search, the controller 40 repeats the operation from the above-described step S10 to drive the recess lamp 30 and the button lamp 38 of the refrigerator 10 to the minimum brightness at night. To facilitate the use of the refrigerator (10).

When the user approaches the refrigerator 10 by using the dispense 14 of the refrigerator 10 in the above state, the pyroelectric sensor 39 detects the proximity of the user and provides a human body detection signal to the controller 40. do.

The controller 40 determines that a person is close to the vicinity of the refrigerator 10 in step S16, and has a logic “high” state as shown in FIG. 5B as the switching transistor Q1 of the lamp driver 36 in step S18. The driving control signal of the two drive mode is output, and in step S20, it is searched whether the lever switch 34 and the operation button 24 interlocked with the operation lever 20 are in an "off" state. At this time, the lamp driver 36 outputs the maximum driving voltage to the recess lamp 30 and the button lamp 38 by the driving control signal of the logic " high "

Therefore, in the state in which the lamp control mode (night mode) of the refrigerator 10 is set to the automatic mode by the above-described operation, the recess area 16 of the dispenser 14 may be opened only by the user approaching the refrigerator 10. By controlling the lighting of the recessed lamp 30 and the button lamp 38 that illuminates the operation button 24 at maximum brightness, the refrigerator can be efficiently used even in a very dark environment.

When the user inserts the cup into the dispenser 14 and operates the operation lever 20 to take out water or ice from the discharge port 18 and then removes the cup, the lever switch 34 interlocked with the operation lever 20 is “ Off ". At this time, the control unit 40 detects this in step S20 of FIG. 4, and ramps the driving control signal of the third driving mode in which the TV ratio is gradually reduced for a predetermined time T _operation as shown in FIG. 5C in step S22. After outputting to the driver 36, the drive control signal for maintaining the minimum brightness is continuously output. At this time, the preset time is preferably set to about 5 seconds, the pulse period is preferably to have a period of 5msec.

That is, the controller 40 outputs the ratio of the turn-on (T _ON ) and the turn-off (T _OFF ) to the lamp driving control signal having the initial logic “high” at 90:10, and then turns on the turn-on (T _ON ) and the turn-off ( The ratio of T _OFF ) is gradually reduced to 10:90 so that the brightness of the recess lamp 30 and the button lamp 38 is minimum. Under the control of the controller 40, the voltage output from the lamp driver 36 is adhesively reduced at the level of Vcc-Vec so that the brightness of the recess lamp 30 and the button lamp 38 is gradually darkened. do.

If the lever switch 34 by the operation lever 20 is not “off” in step S20, the controller 40 determines whether a predetermined time (for example, about 3 seconds or less) has elapsed in step S21. When the operation lever 20 is not operated, the brightness of the lamps 30 and 38 is automatically adjusted by performing the above-described S22 process. The reason for this is to prevent a state in which the lamps 30 and 38 are continuously lit at the maximum brightness when a person just passes by the vicinity of the refrigerator 10 placed at home.

Therefore, when the lamp control mode of the refrigerator of the present invention is automatically set, the surroundings of the recess 16 and the operation button 24 of the dispenser 14 are illuminated with a dim light according to the brightness of the surroundings, and the surroundings of the refrigerator 10 are illuminated. When a person approaches, the recess lamp 30 and the button lamp 38 are driven at maximum brightness, and after taking out water or ice, the brightness of the two lamps 30 and 38 is gradually darkened to minimize the minimum brightness. By maintaining the brightness, it is possible to efficiently use the refrigerator at night.

If the user sets the operation mode to the manual mode (weekly mode) by "off" the mode switch 35, the controller 40 determines that the manual mode is in step S10 of FIG. 4 and the lever switch in step S23. (34), it is searched whether the operation button 22 is "on". If the search result lever switch 34, the operation button 22 is not "on" jumps to the above-described step S10.

When the user inserts the cup into the recessed portion 16 of the dispenser 14 and pushes the operation lever 20 to control the lever switch 24 to be " turned on " or the operation button 22 is pressed to " on " 40 outputs a driving control signal as shown in 5b of FIG. 5 to the lamp driver 36 to light the recess lamp 30 and the button lamp 38 at the maximum brightness.

Then, in step S26, if the lever switch 34 or the operation button 22 is "off", and if it is not "off", the process of S24 is repeated to maintain the brightness of the lit lamps 30 and 38 to the maximum. In addition, it is determined that the lever switch 34 or the operation button 22 is “off”, and the lamp driving control signal of the fourth driving mode having the pulse type as shown in FIG. 5D is output to the lamp driving unit 36 in step S28. The power supply voltage level provided to the recess lamp 30 and the button lamp 38 for a predetermined time is gradually lowered and then turned off.

Referring to FIG. 5D, it can be seen that the duty ratio of the lamp driving control signal is gradually decreased after the duty ratio of the lamp driving control signal is outputted as a logic “low” during the preset time T _operation . It can be seen that the voltage provided to the button lamp 36 is gradually lowered and then cut off to be turned off after the brightness of the lamps 30 and 38 is gradually lowered for a predetermined time.

Therefore, when the lamp control mode is set to the manual mode (daytime mode), the refrigerator lamp control apparatus according to an embodiment of the present invention, the user is located on the operation lever 22 or the operation panel 22 of the door operation button 22 The operation of the recess lamp 30 and the operation button lamp 38 only when the manual operation is performed manually, and the two lamps 30 when the operation lever 20 or the operation button 22 are returned and " off " , 38) The brightness of the "gradual" can be gradually darkened "off" to save power during daytime use.

In addition, in the embodiment of the present invention has been described an example of setting the automatic mode and the manual mode by the mode switch 35, the person who understands the present invention to determine the day and night by the output of the illumination sensor 32 Note that the brightness of the lamp can be adjusted by selecting one of the operating modes.

As described above, the present invention maintains the minimum brightness of the recess lamp and the button lamp in response to the ambient brightness of the refrigerator, and automatically operates the recess lamp and the button lamp when the user approaches the refrigerator or when the operation lever or the operation button is operated. By controlling to the maximum brightness and taking out water or ice from the dispenser or when the operation buttons are completed, the brightness of the lamp is gradually controlled to be dark to effectively utilize or facilitate the use of the refrigerator dispenser placed in a dark place. .

Claims (10)

In the lamp control circuit of the refrigerator, A dispenser provided in the refrigerator door so that water / ice inside the refrigerator can be taken out by the movement of an operation lever installed in the recess of the dispenser located at the front of the refrigerator door; A recess lamp positioned in the recess area of the dispenser and illuminating light of brightness corresponding to an input of a power voltage to the recess area; A lamp driver supplying a power supply voltage corresponding to a driving control signal to the recess lamp; An illumination sensor detecting the ambient brightness of the refrigerator; A biological sensor for detecting the presence or absence of living organisms around the refrigerator; In response to an output of the illuminance sensor, a driving control signal for lighting the recess lamp to the lowest brightness is provided to the lamp driver, and the recess lamp is set to the maximum brightness in response to the detection of the living organism by the biometric sensor. And a control unit for changing the drive control signal and varying the drive control signal such that the recess lamp gradually lowers the illuminance from the maximum brightness to the lowest brightness when the operation lever is returned after operation. Lamp control circuit of the refrigerator. delete The lamp control circuit of claim 1, wherein the biological sensor is a far-infrared sensor or a pyroelectric sensor that detects heat emitted from a human body. According to claim 1 or claim 3, wherein the refrigerator lamp control device is located in the lower portion of the operation panel installed in the refrigerator for setting the temperature of the refrigerator, etc. The illumination panel corresponding to the power supply voltage output from the lamp driving unit Lamp control circuit of the refrigerator further comprising a button lamp for illuminating. The lamp control circuit according to claim 4, wherein a light guide plate is provided between the operation button of the operation panel and the button lamp to guide light emitted from the button lamp in a wide area. The refrigerator according to claim 5, wherein the recess lamp and the button lamp are simultaneously connected to the output node of the lamp driving unit to be driven at the same time so that they are collectively controlled when the operation lever or the operation button is operated by a user. Lamp control circuit. The display apparatus of claim 6, wherein the control unit comprises: a first driving mode for lighting the recess lamp and the button lamp with minimum brightness and a second driving for lighting the two lamps with maximum brightness; A mode, a third driving mode in which the two lamps vary in brightness from the maximum brightness to the minimum brightness within a predetermined time, and a refrigerator outputting the fourth driving mode in which the two lamps are turned off within the predetermined time from the maximum brightness Lamp control circuit. Driving a lamp that emits light in the recessed area of the dispenser at the lowest brightness corresponding to the brightness of the refrigerator; Driving the lamp to the maximum brightness in response to an operation lever provided in the dispenser, an operation of an operation button, or detection of proximity of a refrigerator by a user; Responsive to the return of the operation lever or the operation button is configured to include a lamp brightness control step of controlling the brightness to gradually darken to the lowest brightness for a predetermined time, Searching for a day / night condition in response to an output of an illuminance sensor detecting the ambient brightness of the refrigerator; When the operation of the operation lever is detected in the search result during the day, the lamp is driven to the maximum brightness, and in response to the return of the operation lever, the lit lamp gradually darkens to the minimum brightness for a preset time and turns off. Lamp control method of a refrigerator characterized in that it further comprises controlling to. delete delete

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