KR20100094064A - Washing machine and led controlling method thereof - Google Patents

Abstract

PURPOSE: A washing apparatus and a led control method thereof are provided to make the circuit construction of a microprocessor simple by controlling the colors and the power supply of a number of LEDs using a gate block. CONSTITUTION: A washing apparatus is composed of a cabinet, a control panel, and a gate block. The cabinet forms a frame. The control panel comprises a microprocessor(310). The microprocessor selects and controls washing, rinsing, dehydration and drying functions. The gate block is installed on the control panel. The gate block includes a number of LEDs(370). The LEDs are turned on or off by the microprocessor based on the selected function.

Description

LED control method of washing machine and washing machine

The present invention relates to a washing machine and an LED control method for a washing machine, and more particularly, to a method for controlling the LED of the washing machine and the washing machine which can minimize the number of pins of the microcomputer for the color and on / off control of the LED. will be.

BACKGROUND ART An electronic display, which has been commonly used up to now, constitutes a display surface with a large amount of light emitting diodes (LEDs), and an electromagnetic tube or a liquid crystal display tube may be used instead of the LEDs. Currently, the most used LED tube is long life, high brightness, and there are colors such as R (Red), G (green), and B (blue). LED has a feature that is suitable for high-speed control because the light emitted is bright and the lighting time is short.

A typical electronic LED display combines tens of thousands or even hundreds of thousands of LEDs to form one display surface and controls the LED brightness of the display surface so that the required pattern is displayed. However, LED displays are the most expensive of all electronic displays, which is advantageous for the enlargement of the device, but it is expensive.

For example, about 250,000 monochromatic LEDs are required to form a 500 × 500 pixel screen, and about 500,000 LEDs are required to form a 500 × 500 pixel screen in two colors. Therefore, the larger the number of LEDs, the more expensive the disadvantage.

When the LED is applied to the display unit provided in the control panel of the washing machine, when there are two or more LEDs of R, G, B, and three colors, the pins of the microcomputer are individually controlled by the number of LEDs to control the LEDs individually. It is necessary.

However, in the case of home appliances such as washing machines that do not need to express various colors on the display unit, it is advantageous to simplify the circuit configuration of the microcomputer rather than constructing a complicated circuit to control individual colors of the LED.

Therefore, it is necessary to simplify the circuit configuration of the microcomputer for LED control.

An object of the present invention is to provide a washing apparatus and a method of controlling the LED of the washing apparatus that can minimize the number of pins of the microcomputer for the color and on / off control of the LED.

The present invention to achieve the above object is a cabinet forming an appearance; A control panel installed at one side of the cabinet and provided with a microcomputer to select and control washing, rinsing, dehydration and drying functions; And a plurality of LEDs installed in the control panel and turned on / off by the micom according to a selected function, wherein the control panel is connected to the micom to turn on / off signals to the LEDs by the micom. It provides a laundry apparatus comprising a gate block for transmitting a further.

The LED is characterized by consisting of a three-color LED tube of R (Red), G (Green), B (Blue).

The microcomputer further comprises an RGB port corresponding to each color of the LED tube.

The microcomputer further includes an on / off port corresponding to each of the LEDs.

The gate block is formed corresponding to the number of the respective LED tubes, characterized in that composed of a plurality of end gates for receiving an input signal from the RGB port and on / off port to output to the LED tube.

The number of ports required by the microcomputer is '3 + n' when the number of LEDs installed is 'n'.

In addition, in order to achieve the above object, the present invention, when implementing a specific color of RGB to a specific LED, RGB signal input step of generating an input signal of the corresponding color from the frequency control port of the LED tube that is lit with the corresponding color; An on / off signal generating step of generating a power input signal of the corresponding LED from an on / off port for turning on / off the power of the corresponding LED when an RGB signal is input; And a lighting step of receiving the RGB signal and the on / off signal from the end gate corresponding to the corresponding RGB to turn on the LED tube of a specific color.

The method may further include determining whether to implement a specific color among RGB in the plurality of LEDs before the RGB signal input step.

An RGB signal input step of generating an input signal of a corresponding color from the frequency control port of the LED tube which is lit with the corresponding color when it is determined that the specific color is implemented in the plurality of LEDs in the determining step; An on / off signal generation step of generating a power input signal of the corresponding LED from an on / off port for turning on / off the power of a plurality of LEDs when an RGB signal is input; And a lighting step of receiving the RGB signal and the on / off signal from a plurality of end gates corresponding to the corresponding RGB to light up the LED tube of a specific color.

As described above, the LED control method of the washing apparatus and the washing apparatus according to an embodiment of the present invention can minimize the number of pins of the microcomputer for the color and on / off control of the LED, thereby simplifying the circuit configuration of the microcomputer. It works.

Hereinafter, a drum washing apparatus will be described as an embodiment of the present invention, and the washing machine and the LED control method of the washing apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of the drum washing apparatus according to an embodiment of the present invention, Figure 2 is a plan view showing a control panel according to FIG. 3 is a block diagram showing the relationship between the microcomputer and the LED of the present invention, Figure 4 is a detailed block diagram showing the relationship between the microcomputer and the LED of FIG.

As shown in FIG. 1, the drum washing apparatus according to an embodiment of the present invention includes a cabinet 100 having a large appearance, a tub 110 installed inside the cabinet 100 to store wash water, and It consists of a drum 120 rotatably installed inside the tub 110 and a motor 130 for driving the drum 120, the control panel 300 is provided on the outside of the cabinet 100 washing machine It provides a function button that displays the operating status of the and allows the user to select various functions.

An inlet 100a is formed in front of the cabinet 100 to inject laundry, and the inlet 100a is opened and closed by the door 200.

The upper part of the tub 110 is supported on the upper part of the cabinet 100 by the hanging spring 101, and the lower part of the tub 110 is supported by the friction damper 103 so that the drum 120 rotates at high speed. Reduces vibration generated in the drum washing machine ().

A plurality of lifters 124 are installed on the inner circumferential surface of the drum 120 to raise the laundry introduced into the drum 120 to a predetermined position, and a plurality of through holes are provided to allow the washing water to escape from the drum 120 in a washing process such as dehydration. 122 is formed.

A water supply hose 140 is connected to the upper side of the tub 110 to supply water from the external water source to the tub 110, and a water supply valve 150 is installed on the water hose 140 to control the access of the washing water. do.

Under the tub 110, a drain hose 160 and a drain pump 170 are installed to discharge the wash water used for washing and rinsing to the outside.

The motor 130 mounted at the rear of the tub 110 is coupled to the drum 120 through the rotation shaft 132 to rotate the drum 120.

On the lower side of the tub 110, a heater 180 for adjusting the water temperature of the washing water, a temperature sensor (not shown) for measuring the water temperature of the washing water, a water level sensor (not shown) for detecting the water level of the washing water, and the like. This is installed. These sensors are controlled by the microcomputer 310 formed in the control panel 300.

As shown in FIG. 2, the control panel 300 includes a power button 320 for turning on / off a power of the drum washing apparatus and pauses the operation of the drum washing apparatus. Operation button 330 for restarting, automatic selection button 340 is automatically set when washing, rinsing, dehydration and drying course is set when the user selects the course, and a plurality of functions to select the function as desired by the user Button 350 is provided.

In addition, the control panel 300 is provided with a display unit 360 to display a selected item during the operation of the various selection buttons, the progress of the course and the like to the user.

Various function buttons and the LED 370 is used as a backlight so that the position of the button and the contents displayed on the display unit 360 can be seen in the dark behind the display unit 360. And the display unit 360 and the LED 370 are controlled by the microcomputer 310.

The power button 320, the operation button 330, and the function selection button 350 may allow the user to know the position of the button even in a dark place by the luminescence of the LED 370 used as a backlight. Each LED 370 may implement one color, or may be provided with three color LED tubes 372 of R (Red), G (Green), and B (Blue) to implement various colors.

Hereinafter, an LED having a three-color LED tube will be described in detail as an example of the present invention.

3 and 4, the LED 370 installed in the control panel 300 of the present invention is a three-color LED tube 372 of R (Red), G (Green), B (Blue). A plurality of LEDs 370 are installed and used.

The LED 370 is electrically connected to the microcomputer 310, and the input signals and the on / off input signals for implementing the R, G, and B colors are output to the respective LED tubes 372 through the gate block 316. .

The microcomputer 310 is provided with an RGB port 312 composed of an R port 312a, a G port 312b, and a B port 312c respectively corresponding to R, G, and B colors. In addition, the microcomputer 310 is provided with an on / off port 314 for turning on / off the power of the LED 370, the on / off port 314 is provided as many as the number of the LED (370).

The color input signal of the RGB port 312 and the on / off signal of the on / off port 314 are input to the gate block 316, and the input signal is output to each LED 370.

The gate block 316 is composed of end gates 316 corresponding to the number of LED tubes 372 that are lit in the colors of R, G, and B, respectively. Since one LED 370 is composed of three LED tubes 372, a total of three end gates 316 corresponding to one LED 370 are configured.

Each end gate 316 is input to the input signal and the power on / off signal of the color to be implemented, the input signal is output to the LED tube 372 of the corresponding color through the end gate 316 to implement The color lights up.

For example, if a red LED is to be implemented in the first LED 370 ′ of FIG. 4, the microcomputer 310 sends an input signal to the R port 312a so as to light up the red LED tube 372a, and the input signal is set to the first LED 370 ′. It is input to one end gate 316a. At the same time, a power-on signal is sent to the first on / off port 314a that turns on / off the first LED 370 ', and the power-on input signal is input to the first end gate 316a. When two signals are input, the R-color LED tube 372a of the first LED 370 'is turned on to indicate that the first LED 370' is red.

As another example, if the first LED 370 ′ and the second LED 370 ″ of FIG. 4 are to implement green color, the microcomputer 310 may set an input signal to turn on the green LED tube 372b. Port 312b, and the input signal is input to the first end gate 316a and the second end gate 316b. At the same time, the microcomputer 310 powers on signals to the first on / off port 314a and the second on / off port 314b that turn on / off the first LED 370 'and the second LED 370' '. The power-on input signal is input to the first end gate 316a and the second end gate 316b. When two signals are input to the first end gate 316a and the second end gate 316b, the G color LED tube 372 of the first LED 370 ′ and the G color LED tube of the second LED 370 ″. 372b is lit to indicate that the first LED 370 'and the second LED 370' 'are green.

Since the same color should be implemented in the plurality of LEDs 370, the gate block 316 is preferably capable of implementing a Boolean function of and and or.

As described above, since the color of the LED 370 is implemented, the number of ports required for controlling the plurality of LEDs 370 in the microcomputer 310 is '3 + n' when the number of the installed LEDs 370 is 'n'. Becomes

That is, if the number of installed LEDs 370 is five, the microcomputer 310 is basically provided with three RGB ports 312 for the R, G, B colors, each of the five LED 370 power supply Five on / off ports 314 are provided for turning on / off. Therefore, when five LEDs 370 are installed, eight ports are required for the microcomputer 310.

Conventionally, in the case of three-color LEDs capable of individual color control, when the number of LEDs installed is 'n', the port required for the microcomputer 310 to individually control each color was '3 × n'. Therefore, the present invention has the advantage that the control of the LED (370) if only a few fewer ports than the conventional. However, in the case of the present invention, since it is difficult to control the individual colors, it is preferable to apply when the individual color control is not required for each LED.

In the drum washing apparatus according to an embodiment of the present invention having the configuration as described above, the control method of the washing apparatus will be described as follows (refer to FIGS. 1 to 4).

5 is a flowchart illustrating a control method of a drum washing apparatus according to an embodiment of the present invention.

As shown in FIG. 5, when the microcomputer 310 implements a specific color to a specific LED 370 among the plurality of LEDs 370 installed in the control panel 300, one microcomputer 370 or a plurality of LEDs ( In step 370, it is determined whether to implement a specific color (decision step S10).

If it is determined that the user implements a specific color in one LED 370, such as selecting only one of the function buttons or operating only the display unit 360, the microcomputer 310 generates an input signal of the corresponding color (RGB signal. Input step, S100). For example, if a red LED is to be implemented in the first LED 370 ', the microcomputer 310 sends an input signal to the R port 312a to light up the red LED tube 372a.

When the signal of the corresponding color is input in the RGB signal input step S100, the microcomputer 310 inputs the power on signal of the corresponding color to the on / off port 314 for turning on / off the power of the corresponding LED 370. (On / off signal generation step, S200). For example, when an input signal is generated to turn on the red LED tube 372a of the first LED 370 ', a power-on signal of the first LED 370' is sent to the first on / off port 314a.

After that, the RGB signal and the power-on signal are input to the end gate 316 corresponding to the selected color, and the LED tube 372 of the corresponding color is turned on according to the input signal (lighting step S300). That is, according to the signal input to the first end gate 316a, the R color LED tube 372a provided in the first LED 370 'is turned on.

If it is determined that a specific color is implemented in the plurality of LEDs 370 in the determination step S10 due to a user's function button manipulation and operation of the display unit 360, the microcomputer 310 generates an input signal of the corresponding color. (RGB signal input step, S20). For example, if the first LED 370 ′ and the second LED 370 ″ are implemented in blue, the microcomputer 310 sends an input signal to the B port 312c to light up the blue LED tube 372c. send.

When the signal of the corresponding color is input in the RGB signal input step S20, the microcomputer 310 supplies power of the corresponding color to the plurality of on / off ports 314 that turn on / off the power of the corresponding LEDs 370. An on signal is input (on / off signal generating step, S30). For example, when an input signal is generated to light the blue LED tube 372c on the first LED 370 'and the second LED, the power-on signal of the first LED 370' and the second LED 370 '' is turned on. Is sent to the first on / off port 314a and the second on / off port 314b.

Thereafter, the RGB signal and the power-on signal are input to the end gate 316 corresponding to the selected color, and the LED tube 372 of the corresponding color is turned on according to the input signal (lighting step, S40). That is, according to the signals input to the first end gate 316a and the second end gate 316b, the B color LED tube 372c provided in the first LED 370 ′ and the second LED 370 ″ is provided. Lights up.

In this way, a large number of LED colors and power are controlled, and the number of ports required for the microcomputer is reduced compared to the prior art, thereby simplifying the circuit configuration of the microcomputer.

Meanwhile, the present invention is not limited to the above-described embodiments, and any person having ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention as claimed in the claims. Of course, such changes will fall within the scope of the claims set forth.

1 is a cross-sectional view of the drum washing apparatus according to an embodiment of the present invention.

Figure 2 is a plan view of the control panel according to Figure 1;

3 is a block diagram showing the relationship between the microcomputer and the LED of the present invention.

4 is a detailed block diagram showing the relationship between the microcomputer and the LED of FIG.

Figure 5 is a flow chart illustrating a control method of the drum washing apparatus according to an embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

100: cabinet 120: drum

300: control panel 310: microcomputer

312: RGB port 314: on / off port

316: end gate 370: LED

372: LED Tube

Claims (9)

A cabinet forming an appearance; A control panel installed at one side of the cabinet and provided with a microcomputer to select and control washing, rinsing, dehydration and drying functions; And Installed in the control panel, and comprises a plurality of LEDs on / off by the microcomputer according to the selected function, The control panel further comprises a gate block connected to the microcomputer to transmit an on / off signal to each of the LED by the microcomputer. The method of claim 1, The LED is a washing device, characterized in that consisting of three color LED tube of R (Red), G (Green), B (Blue). The method of claim 2, The microcomputer washing apparatus further comprises an RGB port corresponding to each color of the LED tube. The method of claim 3, The microcomputer further comprises an on / off port corresponding to each of the LEDs. The method of claim 4, wherein The gate block is formed corresponding to the number of the respective LED tube washing apparatus, characterized in that composed of a plurality of end gates for receiving an input signal from the RGB port and the on / off port to output to the LED tube. The method of claim 5, The number of ports required by the microcomputer is a washing apparatus, characterized in that '3 + n' when the number of LEDs installed 'n'. An RGB signal input step of generating an input signal of a corresponding color from a frequency control port of an LED tube which is illuminated with the corresponding color when implementing a specific color among RGB in a specific LED; An on / off signal generating step of generating a power input signal of the corresponding LED from an on / off port for turning on / off the power of the corresponding LED when an RGB signal is input; And And a lighting step of receiving the RGB signal and the on / off signal from the end gate corresponding to the corresponding RGB to turn on the LED tube of a specific color. The method of claim 7, wherein And determining whether to implement a specific color among RGB to the plurality of LEDs before the RGB signal input step. The method of claim 8, An RGB signal input step of generating an input signal of a corresponding color from the frequency control port of the LED tube which is lit with the corresponding color when it is determined that the specific color is implemented in the plurality of LEDs in the determining step; An on / off signal generation step of generating a power input signal of the corresponding LED from an on / off port for turning on / off the power of a plurality of LEDs when an RGB signal is input; And And a lighting step of receiving the RGB signal and the on / off signal from a plurality of end gates corresponding to the corresponding RGB to light up the LED tube of a specific color.

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