FR3055176B1 - INTELLIGENT LED LAMP WITH VARIABLE TINT MICRO COMPUTER - Google Patents

Abstract

The present application discloses a type of intelligent LED lamp controlled by micro-computer variable shade. This intelligent variable-color micro-computer controlled LED lamp includes a power switch, capacitive power supply, microprocessor, LED driver and LED lamp. The electrical switch controls the opening and closing of the current. After closing the switch, the capacitive power supply and the switch connected to the microprocessor provide the latter with a brief electrification. The microprocessor, depending on the frequency of the pulses of the power switch, controls the LED lamp to effect a change of color or color temperature. The LED driving circuit controller acts as a constant voltage generator, and a capacitor is connected to the output terminal of the DC generator sends smooth output waveforms, allowing the LED lamp to not flicker .

Description

An intelligent LED light controlled by a variable color microcomputer

Technical area

The present application involves the field of LED lamps. It includes in particular a type of intelligent LED lamp controlled by microcomputer to variable shade.

Technological context

Currently available LED lamps often use a DC drive system. It often happens that they twinkle. In karaoke or scenic settings, among other environments, this is no problem. So much so that it's a kind of mood. However, applied to domestic use, twinkling has a strong impact on the sense of sight, making it impossible to use in the context of domestic life.

In addition, currently available dimmable LED lamps generally require a switch for each color to be controlled, or must be controlled through a smartphone or intelligent controller, which is extremely inconvenient for their home use. More importantly, LED lamps use red, green, and blue monochrome LEDs, and combine different shades to produce each color. However, the effectiveness of the red, green, blue mixture in order to obtain white light is low. These lamps are therefore mainly used for the purpose of creating mood lighting, and can not substitute traditional white lighting. Greatly limits the use of LED lights in homes. With rising living standards, people's needs for quality of life have also increased little by little. Traditional white or warm white lighting is not able to provide colored mood lighting, and LED lamps are also not able to replace traditional lighting. Therefore, in situations where it is sometimes necessary to enhance the ambient lighting, if it is to mount an LED lamp alone, it is not economically viable and generates a huge waste. This is also a reason for its difficult domestic use.

Practical content of the new model

The purpose of the present application is to provide a type of dimmable microcomputer-controlled intelligent LED lamp with improved structure.

In order to achieve this goal, this application has employed the technological project below.

The present application discloses a type of dimmable microcomputer-controlled intelligent LED lamp comprising a power switch, a capacitive power supply system, a microprocessor, an LED driver circuit controller and an LED lamp. The power switch fully controls the opening and closing of intelligent dimmable LEDs. The capacitive power system and the power switch are connected in parallel to the microprocessor. After closing the power switch, brief electrifications are provided to the microprocessor. The microprocessor, as a function of the frequency of the pulses of the power switch, sends a 20K-70K modulated signal to the LED driver circuit controller, thereby controlling the change in color or temperature. of color emitted by the LED lamp. Specifically, after closing the power switch, while the capacitive power supply system maintains a continuous electrification and the switch opens again - considered a pulse - this causes the change of color or color temperature. The LED driving circuit controller acts as a constant voltage generator, and a capacitor is connected to the output terminal of the DC generator sends smooth output waveforms, allowing the LED lamp to not flicker . Depending on the signal from the LED driver, the LED lamp controls the brightness of its LEDs, changes color or color temperature.

It should be noted that this intelligent dimmable micro-computer-controlled LED lamp uses a DC voltage generator, and a capacitor is connected to the output terminal of the DC generator allowing the LED lamp to not flicker for the naked eye; this would meet the needs of domestic use. It should also be noted that this intelligent LED lamp controlled by variable-tone microcomputer contains a very high capacitance, or capacitive power supply system. This capacitance, after the switch has turned off the electrical power, can still supply the electrical circuit of the control parts of the smart lamp - or microprocessor - with power for a time, usually for about 5 seconds. So after the switch cuts off the power, parts of the intelligent control system can actually continue to work. This intelligent control system can thus obtain the state of power switch, read once the pulses of the switch and make the change of color or color temperature.

But when the switch has closed for more than 5 seconds, he infers that he has already turned off the power and maintains his previous state of color and color temperature. At its next ignition, the bulb will be the same color as before the previous extinction.

What's optimized, The LED bulbs have five groups of monochromatic bulbs: red, green, blue, white and warm white,

It should be pointed out that the LED lamp of this application both white and warm white monochrome bulb groups used in the creations, when it is necessary to use a white or warm white light, directly use these bulb colors for emit monochrome light. It is possible to use them for lighting, thus avoiding the problem of low efficiency of the white light resulting from the mixture of red, green and blue. As a result, LED lamps can also be used for home lighting, and can meet occasional mood lighting needs. The LED lamp of this application only uses the white diode group and the warm white diode array, thus enabling it the lighting function, thus avoiding the problem of low efficiency of the white light resulting from the mixture of red, white and white.

green and blue. By expanding the scope of LED lamps, the domestic application market has opened up to these. Unlike the currently fully colored LEDs in circulation, which use the bulbs of the three RGB colors, the LED light of this application combines all the colors.

What is optimized is that the microprocessor sends a 65K modulated signal to the LED driver.

What is optimized, LED bulb predisposing five states of color or color temperature, divided into warm yellow light, white light, warm white light, variable hue and fixed hue. Depending on the pulse rate of the power switch, the microprocessor switches between the five color states or color temperature.

It should be noted that the LED bulb predisposes five states of color or color temperature for convenience, the warm yellow light of which is produced from a mixture of different proportions of white and warm white light. and the colored lights are produced from a mixture of different proportions of red, green and blue. The gradual change of colored light is the result of the incessant indication of the modification of the proportions of the three colors red, green, and blue, or of a definite rule of modification of the proportions of these same colors; while the fixed color light is derived from a single pulse of the power switch upon the gradual change of light color, indicating to the diode to persist in its current state, no further changes are made. Of course, it is understood that in the absence of a white, warm white or hot yellow monochrome diode, it is possible to mix in different proportions the red, green and blue diodes. In addition, it is also possible to mix red, green and blue to obtain a warm white light; but the efficiency is relatively low.

The beneficial results of this request are:

The microcomputer-controlled smart LED lamp of this application uses a DC voltage generator, and a capacitor is connected to the output terminal of the DC voltage generator and modulates a 20K-70K compatible signal, allowing the LED lamp to not flicker for naked-eye observation, thus resolving the previous major problem of flickering LEDs. In addition, by pulsing the power switch, it is possible to make changes in color or color temperature for simple and practical use, laying the foundation for the use of variable color LED lamps in more home office applications.

Explanation of the illustrations Image 1 is a schematic diagram of the driving structure of the micro-computer controlled variable-color intelligent LED lamp implemented in this example. The image 2 is the diagram of the structure of the micro-computer controlled variable color intelligent LED lamp implemented in this application. The image 3 is the flowchart of the ordered modification structure of the five types of color status or color temperature of the micro-computer controlled variable color variable intelligent LED lamp implemented in this application. The image 4 is the schematic diagram of the structure of the five groups of diodes arranged in the micro-computer-controlled variable color variable intelligent LED lamp implemented in this application. The image 5 is the diagram of a different structure of the five groups of diodes arranged in the intelligent colored LED variable color controlled micro-computer implemented in this application.

On the illustrations, 1 corresponds to the microprocessor, 2 corresponds to the LED driver circuit, 3 corresponds to the lamp, 11 corresponds to a red monochrome diode, 12 corresponds to a green monochrome diode, 13 corresponds to a blue monochrome diode, 14 corresponds to a white monochrome diode, 15 corresponds to a warm white monochrome diode. Concrete method of implementation

Hereinafter, the combination of the detailed implementation and the images provides a more detailed explanation of the present application. The following implementation case is used only for the understanding and explanation of this application, it should not be construed as a limitation of this application.

Example of implementation

This example of a microcomputer-controlled dimmable intelligent LED lamp, as shown in Figure 2, includes a power switch, a capacitive power supply, a microprocessor, an LED driver circuit controller, and a controller. LED lamp. The power switch fully controls the opening and closing of intelligent dimmable LEDs. The capacitive power system and the power switch are connected in parallel to the microprocessor. After closing the power switch, brief electrifications are provided to the microprocessor. The microprocessor, based on the frequency of the power switch pulses, sends a modulated signal in 20 KHz-70K Hz to the LED driver circuit controller, thereby controlling the change in color or temperature of color emitted by the LED lamp. Specifically, after closing the power switch, while the capacitive power supply system maintains continuous electrification and the switch opens again - considered as a pulse - this causes the color or color temperature to change. The LED driving circuit controller acts as a constant voltage generator, and a capacitor is connected to the output terminal of the DC generator sends smooth output waveforms, allowing the LED lamp to not flicker . Depending on the signal from the LED driver, the LED lamp controls the brightness of its LEDs, changes color or color temperature.

In this example, the LED lamp comprises a support and a diode mounted thereon. The LED bulbs contain the five groups of monochromatic bulbs: red, green, blue, white and warm white, including a white monochrome LED emitting white light, a warm white monochrome LED emitting warm white light. For white or warm white, it is also possible to use a combination of different measures of red, green and blue, but with a lower efficiency. Therefore, this example directly uses white monochrome diodes to emit white, and warm white monochrome diodes to emit warm white. A composition with the five monochrome color groups is shown in Figure 4. In addition, image 5 presents another method of compositing with the five monochrome color groups. These also make it possible to obtain as a result

a white or warm white light. It is understood that the fully colored LED lamps used here, composed of diodes of the five monochrome groups, allowing daily illumination, as regards the concrete composition of the monochrome diodes of the five groups, can be modified according to different designs, and not do not limit to both types of images 4 and 5.

This example uses 6000K monochrome white diodes and 3000K warm white diodes. They produce a high current index of color representation. In addition, by controlling the proportion of white and warm white monochrome diodes, it is possible to obtain a wide range of color temperature, a 2700K-6500K light source, with an even higher illumination index. By controlling the proportion of red, green and blue diodes, it is possible to obtain a rich color and a clever scene. The LED lamps in this example employ red, sales and blue monochrome LEDs to create fully colored mood lighting that can even meet the lighting needs of users, also taking into account the ambience results. A lamp, many uses.

The driving circuit controller of this example employs a constant drive method. In addition, it uses the 65K intelligent PWM control signal of the present example of invention and research, thus solving the problem of flickering lamps previously on the market. The main role of the constant voltage generator is to carry out the amplification processing of the signal sent to the processor of the microcomputer, to drive the diode device, in order to obtain different light effects. The principle of the LED constant voltage generator of this example is shown in Figure 1. This generator, after receiving the signal from the 65K control LED emitted by the microprocessor, directly amplifies the pulses of the signal and sends them to the diode device. . This example connects a capacitor to the output terminal of the constant voltage generator, coordinates the control signal 65K coming out of the processor of the microcomputer, to obtain an excellent effect on the diode device, without any flicker. Image 1 shows that the example waveform input is the relatively high frequency waveform A. The output waveform b is slightly smoother under the action of the capacitor. In this way, the LED does not flicker. The control signal at the output of the microprocessor of this example lies in the 20 KHz-70 KHz, and in any case allows the absence of flicker.

The intelligent dimmable LED lamp of this example, LED bulb predisposing five states of color or color temperature, divided into warm yellow light, white light, warm white light, variable hue and fixed hue. Depending on the pulse rate of the power switch, the control system switches between the five color states or color temperature, whose warm yellow light is produced from a mixture of different proportions of white and warm white light. and the colored lights are produced from a mixture of different proportions of red, green and blue. The gradual change of colored light is the result of the incessant indication of the modification of the proportions of the three colors red, green, and blue, or of a definite rule of modification of the proportions of these same colors; while the fixed color light is derived from a single pulse of the power switch upon the gradual change of light color, indicating to the diode to persist in its current state, no further changes are made. Specifically, this example uses 6000K white monochrome diodes and 3000K hot white diodes. They produce a high current index of color representation. By dosing the monochrome white and warm white diodes, it is possible to obtain a warm yellow light of 3000K. Figure 3 illustrates the orderly setting of the five color states or color temperature of this example. By pressing the power switch, it is possible to control the particular method of color change or color temperature as follows: State 1: Pressing the power switch opens the power, the lamp shines. The color / color temperature of the lamp is identical to that at the last extinction. State 2: By adjusting the color or color temperature, press' 2 power switch to turn off the power, thereby closing the power. Within 5 seconds after closing the power, press the switch to reopen the current. At this point, turn off the switch, and the lamp will turn off immediately, ie turn off the switch, the light will turn off, and then turn off the switch again. This will change the color / color temperature. Then, turn the switch off again to turn off the lamp, and turn it off again. This will switch to the next color / color temperature. This example has five types of color / color temperature that can be alternated. Cycle operation amounts to doing 12345123456 ... Thus, colors / color temperatures are changed to loop. If you have found the light you like, there is no need to switch off. The lamp will shine with this color and color temperature.

In picture 2, the 4th color temperature class change is, more precisely, when the switch adjusts to the 4th RGB class change. Starting with the red, green, blue color variation is the entire variation of the color cycle. When the change brings to the desired color, turn off the switch, then again, to enter the 5th class, stopping the variation on the color desired by the user. In this way, it is possible to choose a color among the 160,000 possible by combining red, green and blue. State 3: Turn off the lamp. Refer to Condition 2. After closing the switch, turning it back on within 5 seconds, it will switch to the next color or color temperature. By switching on the switch 5 seconds after turning it off, or within 5 seconds after turning it off, the system will interpret that the lamp should be turned off and the color or color temperature 'then will persist. The next time the switch is turned on, the displayed color will automatically be the one previously recorded.

It should be noted that the predisposition method of the five types of variation of the image 3 is not the only one. The intelligent lamp of the present application is in no way limited to these five changes in color / color temperature. Specifically, according to the different needs of use, it is possible to obtain more functions of predisposition adjustment of light / chromatic control switch.

Above, this is just a good example of implementation of the application. This is in no way a limitation of the technological scope of this application. The technical staff of this industry as part of the construction of this project, can make changes and revisions. Anyone who, in accordance with this technological content, makes any revision or any other change or reworking to the above implementation falls within the scope of the technological project of this application.

Claims (3)

An intelligent LED lamp configured to be controlled by a microcomputer to have a variable color, the intelligent LED lamp comprising: a switch, a capacitive power supply system, a microprocessor, an LED controller, and LEDs, wherein : the switch is configured to control the dimmable LED lamp, the capacitive power supply and the switch are connected in parallel to the microprocessor, the switch is configured so that after it is closed, while the capacitive power supply system maintains a continuous electrification, it opens again to generate electrification pulses that are provided to the microprocessor, the microprocessor is configured to, depending on the frequency of the pulses of the switch, send a signal modulated having a frequency in a range of 20 Kilohertz to 70 Kilohertz to the LED controller, the LED controller reacted t to the modulated signal to control the color or color temperature change emitted by the LED lamp, the LED controller is configured to generate a constant voltage and a capacitor is connected to the constant voltage output so that forms of Smooth waves are delivered to the LEDs, and based on the output waveforms output from the LED circuit controller, the LED lamp is configured to perform color or color temperature changes. The smart LED lamp according to claim 1, wherein the LED lamp comprises LED bulbs including five groups of monochrome bulbs: a red, green, blue, white and a warmer white color temperature. The smart LED lamp according to claim 1, wherein the LED lamp has five states of color or color temperature including a yellow light, a white light, a warmer white color, a variable color and a fixed color. based on the pulse rate of the switch, the microprocessor is configured to change between the five states of color or color temperature.