TW201026137A - Intelligent LED lighting system - Google Patents

Abstract

A intelligent LED light system comprises at least one LED module, a sensing module, a control circuit, and a driving circuit. The sensing module can automatically detect the brightness, hues, and color temperature in the environment, and also can automatically detect the temperature in the environment. The control circuit adjusts the output circuit of the driving circuit according to the detected values of the sensing module in order to make the final detected values of the sensing module meet the default values stored in the control circuit.

Description

201026137 IX. INSTRUCTIONS: TECHNICAL FIELD The present invention relates to a smart LED lighting system, and more particularly to an illumination system capable of sensing light and temperature conditions in an environment and automatically adjusting light output conditions. [Prior Art] Due to low power consumption, small size and long service life, Φ is widely used in the indicator lights of household appliances, backlights of liquid crystal displays, graphic display screens and third brakes of automobiles. Applications such as lights. In recent years, light-emitting diode materials such as aluminum gallium indium phosphide (AlGalnP) and aluminum gallium indium nitride (A1GaInN) have been successfully developed, so that conventional incandescent light bulbs can be replaced with light-emitting diode elements in many applications. At present, the light-emitting diode lighting device converts the indoor alternating current into a low-voltage direct current by using a transformer, and the light-emitting diode element or the light-emitting diode module is driven by the current to emit light. However, to control the brightness of the illuminator φ, a variable resistor is needed to adjust the current, that is, the knob of the variable resistor must be manually operated to set the brightness. Since the source of light in the environment is not from the lighting device, it is often affected by the change of outdoor sunlight, and the light transmitted from the window in the morning, noon and dusk will change the indoor lighting state. Therefore, if it is necessary to maintain a certain brightness or a fixed illumination state in the room, it is necessary to continuously adjust the manpower, which is not only inconvenient to use, but also often adjusts to a high-brightness output mode to save energy. On the other hand, the current lighting device can use the light generated by the red, blue and green light-emitting 7L parts of the light-emitting diode module to mix different colors of output light, 201026137, so that the required color can be adjusted according to the situation or season, for example: Illuminated in warm tones in cold winters. However, since the mixing and blending of red, blue and green light is not a simple linear relationship, it is not a simple task to adjust only by manpower. Fig. 7 is a circuit diagram of a light-emitting device disclosed in Japanese Laid-Open Patent Publication No. 2,539,743. The light emitting device 700 includes a plurality of light emitting units 714R, 714G, 714B and a plurality of light sensing elements 72〇r, 720G, 720B 'where the red light sensing element 72OR is used to detect red light emitted by the light emitting unit φ 714R The luminance, green light sensing element 720G is for detecting the green light luminance emitted by the light emitting unit 714G, and the blue light sensing element 720β is for detecting the blue light luminance emitted by the light emitting unit 714B. The light emitting units 714R, 714G, and 714B constitute a light emitting module 714. The light sensing elements 720R, 720G, 720B and the amplifying circuit 730 are connected to amplify the sensed signal. The illuminating device 700 further includes a plurality of current driving units 712 and a plurality of control elements 750. Each of the current driving units 712 supplies a current required for each of the illuminating units to generate light ′, and each of the control elements 75 〇 respectively Φ according to a preset light intensity reference. The value differs from the difference in color light output from each of the illumination units to output a control drive signal that is produced by comparison element 74A, respectively. However, the light sensing elements 72〇r, 72〇g, 72〇B in the light-emitting device 700 detect only the light-emitting units 714R, 714G, and 714B, respectively, and control the light-emitting device 700 to maintain a fixed light output condition, and the whole environment. The light parameters (brightness, chromaticity or color temperature) of the light or the room temperature are not related to heat. In addition, the Republic of China No. M282097 discloses an automatic illumination device having both object sensing and brightness detection, having a body infrared module capable of sensing ambient temperature and a brightness detecting mode 201026137 group capable of detecting ambient brightness. The brightness detecting module is configured to detect the ambient brightness of the surroundings, and output a second turn-on signal when the detected brightness value is lower than a set value. The illumination source module can be illuminated by the second turn-on signal. The automatic lighting device can only turn on the illumination function when it senses that the brightness does not reach a set value. That is to say, the 'automatic lighting device only performs the action of simply lighting the light, and cannot adjust the light output condition instantly and intelligently with the change of the light in the environment, that is, it is not a feedback type (closed) control circuit but simple Open control circuit.综 In summary, there is a need in the market for an illumination system that automatically senses the light state and ambient temperature in the environment and automatically adjusts the light output conditions, and automatically adjusts the light output conditions to improve the various shortcomings of the existing lighting devices. . SUMMARY OF THE INVENTION The present invention provides a smart LED illumination system that can automatically sense the state of light and temperature in an environment, and can adjust the light emitted by the LED module Φ, thereby enabling ambient light. The preset state is reached. The invention further provides a human-friendly light-emitting diode lighting system that can automatically adjust the brightness, chromaticity or color temperature of the output light according to an individual's preference or the overall environment. The invention further provides a power-saving LED lighting system, which can maintain constant brightness illumination at a predetermined point by the closed control loop design, thereby effectively reducing the power consumption. In order to solve the above problems, the present invention discloses a smart LED lighting system characterized by comprising at least a light emitting diode module; at least one 201026137 driving circuit, which generates a driving current to supply the light emitting diode module. Generating light; at least one sensing module capable of detecting light parameters and wrinkles in the lighting environment, and a control circuit for commanding the driving circuit to adjust the driving according to the value of the light parameter and the calorie measured by the sensing module Current; when the measured values respectively meet respective preset criteria, the control circuit commands the drive circuit to temporarily maintain the current value of the drive current. The illumination system further includes a cover that homogenizes the light emitted by the LED module or has a light guiding effect to direct light to the unexposed surface of the housing. The control circuit can command the driving circuit to adjust the output current by means of wireless transmission, and can control a plurality of independently driven LED modules to output predetermined light. The invention further discloses a smart LED illumination system, characterized in that it comprises: at least one LED module, comprising a LED circuit and at least one lamp; at least one driving circuit, which generates a driving current supply ® light-emitting diode module to generate light; at least one sensing module capable of detecting light parameters, temperature or sound in a *, ,, month environment; a control circuit for measuring the light according to the sensing module The parameter and the temperature value command the driving circuit to adjust the driving current; when the measured value respectively meets each preset standard, the control circuit commands the driving circuit to temporarily maintain the current value of the driving current. The intelligent light-emitting diode lighting system of the invention can automatically sense the light state and the temperature in the environment, and can adjust the light emitted by the light-emitting diode module, so that the lighting can be set according to personal preference or the overall environment. The system 201026137 automatically adjusts the brightness, chromaticity or color temperature of the output light. The closed-loop control circuit design can maintain the constant brightness illumination of the stomach to the pre-dip point, so that the power consumption can be effectively reduced. [Embodiment] FIG. 1 is a block diagram of the smart LED illumination system of the present invention. The illumination system 10 includes a light emitting diode module 14, a sensing module 13 and a control circuit 12 and a driving circuit 11. The sensing mode and the group 13 can automatically detect relevant parameters of the light in the lighting environment, such as brightness, chromaticity or color temperature, and can automatically detect the temperature in the environment; it can include a brightness meter, a color juice, and a color. The equivalent sensing circuit of the s meter or thermometer, rather than the single-corresponding sensing of the respective light components of red (R), 4 (G), and blue (b) in the mixed light. Moreover, the control circuit can adjust the driving current output by the driving circuit 11 according to the value of the light parameter and the temperature measured by the sensing module 13, and finally the parameters measured by the sensing module 13 and the temperature values respectively meet the values. Each preset threshold value within the control circuit 12. That is, when the sensing module 13 detects that the relevant parameter value of the light and the preset value are within an allowable range, the driving current of the medium output temporarily remains solid. Similarly, the sensing module 13 detects When the temperature difference between the environment and the corresponding preset value is within an allowable range, the drive current output from the drive circuit 11 is temporarily maintained constant. When the illumination system 10 has a plurality of independently driven LED modules 14, the control circuit 12 can command a plurality of drive circuits n to drive the separate LED modules 14 respectively. In this embodiment, the LED module 14 includes a first illumination unit 141, 201026137, a second illumination unit 142, and a third illumination unit 143. Each of the illumination units 141-143 is driven by a current driving unit iu_u3 in the drive circuit u. . Moreover, the light emitted by each of the light-emitting units 141_143 (for example, red light, green light, and blue light), daylight or natural light source, and other artificial light sources form a mixed light, and the sensing module 13 senses the result of the mixed light in the environment as a whole. . When the sensing module 13 detects that the temperature in the environment is significantly lower than the corresponding preset value (the preset range is the lowest value), the control circuit 12 can command the driving circuit u β to output a suitable driving current, so that the LED module is enabled. The light emitted by 14 tends to be distributed in the warm-toned spectrum, so that people can feel the obvious warmth. Conversely, when the sensing module 13 detects that the temperature in the environment is significantly higher than the corresponding preset value (the highest value in the preset range), the control circuit 12 can command the driving circuit to output a suitable driving current, so that the light is emitted. The light emitted by the polar body module 14 tends to be distributed to the cold tone spectrum, so that people can feel the coolness. Alternatively, the illumination system 10 can change the color temperature of the output light according to the temperature in the environment. When the temperature is low, the color temperature of the output light is lowered; otherwise, the color temperature is increased. In this embodiment, the comparison element 15 can compare the correlation parameter of the light in the environment or the difference between the temperature and the corresponding preset value, and the control circuit 12 outputs the appropriate driving current according to the difference command driving circuit u instead of a single corresponding Comparing and sensing the respective light components of red (R) green (G) and blue (B) in the mixed light. In addition, the control circuit 12 can command the driving circuit 11 to adjust the output current by means of wireless transmission or signal line transmission, and Controlling a plurality of the light emitting diodes-10-201026137 The module 14 outputs predetermined light. The sensing module 13 may include a plurality of sensors placed at different detection points. Therefore, the control circuit 12 can be based on different sensors. The return value is used to adjust the driving current required by the LED module 14. Figure 2 is an application example of the smart LED illumination system of the present invention. There are two illuminations in the space where the user 8〇 is located. The diode modules 24, 242 are respectively driven by the two driving circuits 211, 212 to illuminate. The sensors 231, 232 and 233 can be placed at the required location according to the preferences of the user 80. Detect phase at a specific location Turning on the light parameter and the temperature value, one of the sensors 23 1 directly transmits the sensed value to the control circuit 22 by using the signal line, and the other two sensors 232 and 233 transmit the measured value by wirelessly. The sensors 231, 232, and 233 are not singly corresponding to the respective light components of the red (R), green (G), and blue (B) in the mixed light. When the control circuit 22 receives each sensed value, Compared with the preset value stored internally, if the difference is within an allowable range, the driving current of the driving circuit 211 or 212 is maintained. Of course, the user 8 can also set the preset value by the remote controller 25 on the hand, or select Various lighting modes built into the control circuit 22, such as: highlight mode, dim mode, color wheel mode, etc. As shown in FIG. 3, 'the light-emitting diode module 331 can be compatible with the current fluorescent lamp holder. The 332, 333 and the driving circuit 32 are integrated into the cylindrical housing 34 and disposed on both sides of the LED tube 30 to be fixed to the electrode portion 31 of the socket. The housing 34 can be used for the LED module 33 1,332 and 333 issued 201026137 light uniformity, 4 and ancient soil # times, Most of the light guide effect of the guide (indirect light receiving portion) of the blade surface area emitted Bu., And, modules 331, 332 and 333 may be light-emitting diode element 334 are arranged in a different pattern of light-emitting diode.

The light-emitting diode elements 334 of different colors of red, blue and green can be controlled to combine light of various colors, and the driving circuit 32 respectively adjusts the driving of the red, blue and green light-emitting diode elements 334 according to the command of the control circuit Μ. Current. The wavelength distribution of the special S color temperature ray 41 in the control circuit 22 as shown in Fig. 4 may be composed of different intensity blue light 42, green light 43, and red light 44. Fig. 5 is a block diagram showing a smart LED illumination system according to another embodiment of the present invention. The illumination system 50 includes a light-emitting diode module 54, a sensing module 53 and a control circuit 52 and a driving circuit 51c. The sensing module 53 can automatically detect relevant parameters of light in the lighting environment, for example, brightness. Chromaticity or color temperature, etc. 'instead of single-corresponding to the respective light components of red (R), green (G), and blue (B) in the mixed light' can simultaneously detect the temperature of the environment or the decibel of the sound; An equivalent sensing circuit can be included that includes a luminance meter, colorimeter, color difference meter, thermometer, or decibel meter. Moreover, the control circuit 52 can adjust the driving current output by the driving circuit 51 according to the light parameter measured by the sensing module 53 and the decibel of the temperature or the sound, and finally the light parameter measured by the sensing module 53. The temperature and the decibel number of the sound respectively correspond to the preset values in the control circuit 52. That is, when the sensing module 53 detects that the relevant parameter value of the light and the preset value are within an allowable range, the driving current output by the driving circuit 51 is temporarily fixed -12-201026137; similarly, the sensing mode When the group 53 detects that the temperature or the decibel number of the sound in the environment is within an allowable range of the corresponding preset value, the drive current outputted by the drive circuit 51 is temporarily maintained constant. The LED module 54 includes at least a light-emitting diode circuit 541 and at least one light-emitting device 542, which is an ordinary light-emitting device that emits white light, thereby improving the brightness of the overall output light of the light-emitting diode module 54. In order to make the output light of the LED module 54 uniform, a uniform mask can be added to the light-emitting surface to prevent the brightness or color distribution of the output light from being uniform. The driving units 513-511 of the driving circuit 51 respectively generate currents Ir, Ig, and ratios for driving the red, green, and blue light-emitting diodes in the light-emitting diode circuit 541, and the driving unit 514 generates a driving current for starting the lamps 542. Control circuit 52 generates control signals PWM_R, PWM_G, PWM_B to control drive units 511-311, respectively, and generates an on or off (〇N/〇FF) media unit 514. The illumination system 50 further includes a remote controller 55 and a communication module 57 for setting parameters and modes by using a wireless signal. The communication module 57 can convert the wireless signals of the sensing module 53 and the remote controller 55 into the control circuit 52. The signal format, the control signals PWM-R, PWM-G, and PWM-B of this embodiment are signals generated by pulse width modulation (PWM) technology. In addition to the remote controller 55, the setting parameters and setting modes can also be performed via the wired routing computer 56. In addition, the illumination system 50 further includes a power supply module 58 that is responsible for converting the indoor AC or battery pack to which the system is connected to the DC or AC power required by the associated circuit or module. Fig. 6 is a block diagram showing a smart LED lighting system of another embodiment of the present invention - 13· 201026137. Compared with the LED module 54 of the illumination system 60 of the present embodiment, a dimmable power-saving bulb 642 is used in place of the conventional lamp 542, and the dimmable power-saving bulb 642 can be changed. The light parameter such as the brightness of the drive current Ir is adjusted to be a simple switching of light or dark. The drive circuit 51, the drive Cuiyuan 614 will generate the drive current Iw, and the control circuit 52 corresponding output control signal PWM-W to the drive unit 614. Referring to Figure 6, the sensing module 53 includes a power supply module 534, sensing Circuit 531, control circuit 532 and communication module 533. The sensing circuit 531 can sense the relevant parameters of the sound, light and temperature in the environment, and the output signal of the sensing circuit 531 is processed by the control circuit 523, and then converted into a wireless signal by the communication module 533. The sensing circuit 531 can accept the input of a sound source and output the sound intensity of each frequency band according to the preset frequency band division processing, and the sensing module 53 1 includes an equivalent sensing circuit of the audio filter or the decibel meter. The remote controller 55 includes a communication module 551, a control circuit 552, and a power module.

A 553. The parameter or mode set by the user generates a corresponding signal via the control circuit 552. Similarly, the communication module 551 converts the signal into a wireless signal. The power module 534 and the power module 553 respectively convert the indoor AC or battery pack connected to the system into the power required by the sensing module 53 and the remote controller 55. The technical contents and technical features of the present invention have been disclosed as above, and those skilled in the art can still make various substitutions and modifications without departing from the spirit and scope of the invention. Therefore, the scope of the present invention is not limited by the scope of the invention, and the invention is intended to cover various modifications and modifications of the invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a smart LED illumination system of the present invention, FIG. 2 is an application example of the smart LED illumination system of the present invention; FIG. 3 is an illumination of the present invention; FIG. 4 is a schematic diagram of a composite light source wavelength according to another embodiment of the present invention; FIG. 5 is a block diagram of a smart light emitting diode illumination system according to another embodiment of the present invention; A block diagram of a smart light emitting diode illumination system of an embodiment; and FIG. 7 is a circuit diagram of a light emitting device disclosed in Chinese Patent Publication No. 200539743. [Main component symbol description] 11 Drive circuit 13 Sensing module 15 Comparison component 25 Remote control 31 Electrode part 34 Cover 42 Blu-ray 44 Red light 51, 5Γ Drive circuit 53 Sensing module

10 Lighting system 12 Control circuit 14 Light-emitting diode module 22 Control circuit 30 Light-emitting diode lamp 32 Drive circuit 41 Specific color temperature light 43 Green light 5G '60 Lighting system 52 Control circuit -15- 201026137

54, 54, LED module 55 remote control 56 Xue Cong electric foot 57 communication module 58 power supply module 80 user 111-113 current driving unit ι41 first lighting unit 142 second lighting unit 143 second lighting Unit 211, 212 drive circuit 231 '232' 233 sensor 241 331 , 242 light emitting diode module, 332, 333 light emitting diode module 334 light emitting diode element 511 - 514 driving unit 531 sensing circuit 532 Control circuit 533 Communication module 534 Power module 541 Light-emitting diode circuit 542 Lamp 551 Communication module 552 Control circuit 553 Power module 700 Light-emitting device 712 Current driving unit 714 Light-emitting module 714R, 714G, 714B Light-emitting unit 720R, 720G 720B Light Sensing Element 730 Amplifying Circuit 740 Comparing Element 750 Control Element 16-

Claims (1)

201026137 X. Patent application scope: 1 · A smart LED illumination system comprising: at least one LED module; at least one driving circuit that generates a driving current to supply the LED module to generate light At least one sensing module capable of detecting light parameters and temperature in the lighting environment, and a control circuit for commanding the driving circuit to adjust the driving current according to the value of the light parameter and the temperature measured by the sensing module; When the measured values respectively meet the respective preset criteria, the control circuit commands the drive circuit to temporarily maintain the current value of the drive current. 2. The smart LED lighting system of claim 1, wherein the light parameter comprises brightness, chromaticity or color temperature. 3. The smart LED lighting system of claim 1, wherein the control circuit commands the driving circuit to adjust the driving current by wireless transmission. 4. The smart LED lighting system of claim 1, wherein the control circuit controls a plurality of independently driven LED modules. 5. The smart LED lighting system according to the claims, further comprising a cover for homogenizing the light emitting diode module. 6. The smart LED lighting system according to claim 5, wherein the housing has a light guiding effect, and the light is directed to the uncovered surface of the housing and penetrates to the outside. -17- 201026137 7. According to claim 1 A smart LED lighting system, wherein the preset standard is an allowable range centered on a preset value. 8. The smart LED lighting system of claim 1, wherein the sensing module transmits the measured value to the control circuit by wireless transmission. 9. The smart light emitting diode illumination system according to the claim, wherein the sensing module comprises a plurality of sensors disposed at different locations. Φ ι〇. The smart LED lighting system according to claim 1, wherein the LED module and the driving circuit are integrated into a light-emitting diode lamp, and the LED lamp is additionally The utility model comprises a cylindrical outer cover and two electrode parts. 11. The smart LED lighting system of claim 1, wherein the sensing module comprises an equivalent sensing circuit of a luminance meter, a colorimeter, a color difference meter or a thermometer. A smart LED lighting system comprising: 9 at least one LED module comprising a light emitting diode circuit and at least one light fixture; at least one driving circuit for generating a driving current to supply the light emitting diode module Grouping to generate light; at least one sensing module 'which can detect light parameters, temperature or sound in a lighting environment; and a control circuit that commands the driving based on the value of the light parameter and temperature measured by the sensing module The circuit adjusts the driving current; when the measured value respectively meets each preset standard, the control circuit commands the driving circuit to temporarily maintain the current value of the driving current when it is -18-201026137. A smart light emitting diode illumination system according to claim 12, wherein the light line parameter comprises brightness, chromaticity or color temperature. The smart LED lighting system according to claim 12, wherein the sensing module receives an input of a sound source and divides the processing according to a predetermined frequency band to output the sound intensity of each frequency band. 15. The smart LED lighting system of claim 12, wherein the output light of the lamp is adjustable. 16. The smart LED lighting system of claim 15 wherein the driving current adjusts the output light of the luminaire. 1 7. The smart LED lighting system of claim 12, wherein the output light of the lamp is white light. 1 . The smart LED lighting system according to claim 12, wherein the control circuit commands the driving circuit to adjust the driving current by means of wireless transmission. φ 1 9. The smart LED according to claim 12 The body lighting system, wherein the control circuit can control the plurality of independently driven LED modules. 20. The smart LED lighting system of claim 12, further comprising a housing that homogenizes the light emitting diode module. A smart light-emitting diode lighting system according to claim 20, wherein the outer cover has a light guiding effect to direct light to the uncovered surface of the outer cover and to the outside. 2 2. According to the smart LED lighting system of claim 20, the pre-set standard in the U is a permissible range centered on a preset value. • 19· 201026137 The smart LED illumination system according to claim 12, wherein the sensing mode is transmitted to the control circuit by wireless transmission. 24' The smart LED illumination system of claim 12, wherein the sensing module comprises a plurality of sensors disposed at different locations. 25. The smart LED lighting system of claim 12, wherein the light-emitting diode module and the driving circuit are integrated into a light-emitting diode lamp, the light-emitting diode lamp further comprises a cylinder The outer cover and the two electrode portions 26. The smart LED lighting system according to claim 12, wherein the sensing module comprises a brightness meter, a colorimeter, a color difference meter, a thermometer, an audio filter or a decibel meter Equivalent sensing circuit. 27. The smart LED lighting system of claim 12 further comprising a communication module for receiving and transmitting wireless transmission signals. 28. The smart LED lighting system of claim 12, further comprising a power supply module for supplying power to the system. 2 9. The smart LED lighting system according to claim 12, wherein the power supply module is connected to the indoor AC or battery pack