The present disclosure relates to the technical field of adjustable color-temperature LED lighting devices. More particularly, the present disclosure relates to an LED lighting device capable of adjusting color temperature by a software and hardware cooperative control to achieve high-performance output, so that a constant power can be outputted by performing a direct hardware current modulation and then a software modulation to improve the working efficiency of the LED.
In recent years, light emitting diodes (LEDs) have been popular to the public and are widely used in daily lighting devices, and LED components are roughly divided according to their light emitting characteristics into a high color temperature LED component with a blue luminous color and a low color temperature LED component with a yellow luminous color. Therefore, there are lighting devices with adjustable color temperature on the market, which are provided for users to change and set a light color according to different combinations of high color temperature LED components and low color temperature LED components to meet actual application requirements. For example, a lighting device having a red LED, a green LED, a blue LED and a white LED can use each of the LEDs to statically output a monochromic beam of a red, green, blue or white light, and also can use the LEDs to dynamically mix the lights to output various color beams. Obviously, the four LEDs share the electric energy outputted by an LED drive circuit, so that the four LEDs will receive a quarter of total power separately when the mixed light is set to full brightness, and when the monochromic full-brightness lighting is turned on and the single LED receives the total power, the light emitting efficiency of the LED will decrease and fail to meet user requirements, due to the physical property of the LED (wherein, the larger the power, the smaller the efficiency).
In view of the aforementioned drawback of the conventional LED lighting device, it is a main subject for this disclosure to find a way to maintain the working power substantially carried by the LED when switching the lighting mode of the LED in order to overcome the drawback of the prior art.
In view of the aforementioned problems, it is a primary objective of the present disclosure to provide an adjustable color-temperature LED lighting device that switches to a high or low current by hardware directly and modulates the pulse width by software in order to make the LED drive power constant during the modulation of color temperature, and achieve high-performance light output.
To achieve the foregoing and other objectives, the present disclosure discloses an LED lighting device capable of adjusting color temperature by a software and hardware cooperative control to achieve high-performance output, and the LED lighting device includes at least one light source and a drive circuit. The light source includes a first-wavelength LED, a second-wavelength LED, a third-wavelength LED and a fourth-wavelength LED. The drive circuit is electrically coupled to the light source and includes a primary power output unit, a microcontroller unit and a hardware current switching unit, a secondary power output unit and a constant power programming unit, and the microcontroller unit is telecommunicatively coupled to the hardware current switching unit, and the secondary power output unit is electrically coupled to the primary power output unit, the hardware current switching unit, and the constant power programming unit, and the primary power output unit outputs a maximum drive power to the secondary power output unit. When the microcontroller unit receive a drive signal to learn that only one of the first-wavelength LED, the second-wavelength LED, the third-wavelength LED and the fourth-wavelength LED receives a maximum rated current, the hardware current switching unit switches the resistance of the secondary power output unit to output four times of the maximum drive power to the corresponding first-wavelength LED, second-wavelength LED, third-wavelength LED or fourth-wavelength LED. When the microcontroller unit receives the drive signal to learn that the first-wavelength LED, the second-wavelength LED, the third-wavelength LED and the fourth-wavelength LED receive a quarter of the maximum rated current separately, the hardware current switching unit switches the resistance of the secondary power output unit to output a quarter of the maximum drive power to the first-wavelength LED, the second-wavelength LED, the third-wavelength LED and the fourth-wavelength LED separately, and the constant power programming unit modulates the pulse width of the output power to maintain the carrying power of the light source to be a constant rated power.
Wherein, the first-wavelength LED, the second-wavelength LED, the third-wavelength LED and the fourth-wavelength LED are a red LED, a green LED, a blue LED and a white LED respectively. The maximum rated current is 1.4 A, and a quarter of the maximum rated current is 0.35 A. The LED lighting device capable of adjusting color temperature further includes a modulator telecommunicatively coupled to the microcontroller unit for transmitting the drive signal. The constant power programming unit modulates the pulse width of the output power by a pulse width modulation (PWM) technology. The secondary power output unit has an output control element which is a metal oxide semiconductor field effect transistor (MOSFET). The adjustable color-temperature LED lighting device further includes a cooling element connected to at least one of the light source and the drive circuit, and the cooling element has a power dissipation wattage equal to the rated power wattage carried by the light source.
In summation of the description above, this disclosure uses the hardware current switching unit to switch the resistance of the secondary power output unit to output four times of the maximum drive power for the monochromic full-brightness light during the modulation of color temperature (wherein the first-wavelength LED, the second-wavelength LED, the third-wavelength LED or the fourth-wavelength LED is turned on with the maximum brightness). When the four color LEDs are lit and in a mixed light status, the hardware current switching unit switches the resistance of the secondary power output unit to output a quarter of the maximum drive power, and the constant power programming unit modulates the pulse width of the output power by a software modulation technology to maintain a constant rated power carried by the light source. In this way, the overall light output efficiency of the device and the economic value of the product can be improved.
In other words, the discloser of the present disclosure has continuously collected practical data and found that when the four color LEDs are all turned on and situated a mixed light state, the LED working power cannot be reduced substantially and the attenuation of the LED light emitting efficiency cannot be avoided, if only the pulse width is adjusted through the PWM technology to achieve the purpose of reducing the carrying power of the LED. For this reason, this disclosure designs the hardware current switching unit to directly set the hardware current carried by the LED, and then adjusts the pulse width through the PWM technology to provide the constant working power of the LED, so as to truly improve the light emitting efficiency of the light source and the overall product quality.
This disclosure will now be described in more detail hereinafter with reference to the accompanying drawings that show various embodiments of the invention.
With reference to
With reference to
The modulator 12 can be telecommunicatively coupled to the microcontroller unit 111 through the Remote Device Management (RDM) protocol and Digital Multiplex (DMX) protocol to transmit a drive signal for modulating and adjusting the color temperature. Step S1: When the microcontroller unit 111 receives the drive signal, the drive signal is analyzed to determine whether only one of the first-wavelength LED 100, the second-wavelength LED 101, the third-wavelength LED 102 and the fourth-wavelength LED 103 receives a maximum rated current (such as 1.4 A). If yes, then go to Step 10, or else go to Step 2.
Step S10: The microcontroller unit 111 drives the hardware current switching unit 112 to switch the resistance of the output control element of the secondary power output unit 113 to output four times of the maximum drive power to the corresponding first-wavelength LED 100, second-wavelength LED 101, third-wavelength LED 102 or fourth-wavelength LED 103.
Step S3: The constant power programming unit 114 modulates the pulse width of the output power by a PWM technology to maintain the carrying power of the light source 10 to be a constant rated power.
Step S2: The microcontroller unit 111 analyzes and determines whether the drive signal indicates that the first-wavelength LED 100, the second-wavelength LED 101, the third-wavelength LED 102 and the fourth-wavelength LED 103 receive a quarter of the maximum rated current such as 0.35 A separately. If yes, then go to Step S20.
Step 20: The hardware current switching unit 112 switches the resistance of the output control element to make the secondary power output unit 113 output a quarter of the maximum drive power to the first-wavelength LED 100, the second-wavelength LED 101, the third-wavelength LED 102 and the fourth-wavelength LED 103 separately, and the Step S3 is carried out to modulate the pulse width of the output powerby the constant power programming unit 114 in order to maintain the carrying power of the light source 10 to be a constant rated power. In addition, the cooling element 13 has power dissipation wattage equal to the rated power wattage such as 100 W carried by the light source 10.
Number | Name | Date | Kind |
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8080819 | Mueller | Dec 2011 | B2 |