WO2018223247A1 - Light emitting diode - Google Patents

Light emitting diode Download PDF

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Publication number
WO2018223247A1
WO2018223247A1 PCT/CN2017/000383 CN2017000383W WO2018223247A1 WO 2018223247 A1 WO2018223247 A1 WO 2018223247A1 CN 2017000383 W CN2017000383 W CN 2017000383W WO 2018223247 A1 WO2018223247 A1 WO 2018223247A1
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Prior art keywords
voltage
power
led
module
emitting diode
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PCT/CN2017/000383
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French (fr)
Chinese (zh)
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吕光辉
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吕光辉
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Priority to PCT/CN2017/000383 priority Critical patent/WO2018223247A1/en
Publication of WO2018223247A1 publication Critical patent/WO2018223247A1/en

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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B47/00Circuit arrangements for operating light sources in general, i.e. where the type of light source is not relevant
    • H05B47/10Controlling the light source

Definitions

  • the present invention relates to an apparatus for a Light-Emitting Diode (LED) driver.
  • LED Light-Emitting Diode
  • a LED driver is a device that adjusts the power to an LED or multiple LEDs.
  • LED drivers can be responsive to the needs of LEDs or LED circuits by providing a fixed amount of power to the LEDs as their electronic characteristics change with temperature.
  • the LED driver is an independent power supply that has an output corresponding to the electronic characteristics of the LED.
  • the LED driver can provide dimming by means of a pulse width modulation circuit and can have more than one channel for separate control of different LEDs or LED arrays.
  • the LED power level is fixedly maintained by the LED driver by an increase in temperature and a decrease in electronic characteristics of the LED driver as viewed by the LED or LEDs. Therefore, without a suitable driver or system, the LEDs may overheat or become unstable, thereby performing poorly or failing.
  • the existing LED driver rectifies an alternating current (AC) full-wave waveform into an AC half-wave waveform through a bridge integrated circuit (IC) before providing the required power to the LED.
  • AC alternating current
  • IC bridge integrated circuit
  • MOS Metal Oxide Semiconductor
  • the problem of power loss is based on a power supply that uses an AC half-wave waveform.
  • the starting voltage of the LED is a direct current (DC) power supply, power loss occurs.
  • An aspect of the invention relates to a system for providing a starting voltage to a light emitting diode unit, the system comprising: a bridge module for rectifying an alternating current full wave waveform from a power source into an alternating current half a waveform circuit module having a metal oxide semiconductor, the step-down circuit module for rectifying the AC half-wave waveform into a DC power supply for the LED unit, wherein the step-down circuit The module uses a power factor adjustment module to perform power factor correction and uses a flow control LED to control the wafer to rectify a full voltage so that the DC power source corresponds to the startup voltage of the LED unit Receiving the full voltage to be supplied to the light emitting diode unit.
  • the bridge module is a bridge circuit.
  • the light emitting diode unit is a light emitting diode driver having an integrated circuit.
  • the light emitting diode unit has a current limit set by a metal oxide semiconductor power transistor
  • the voltage of the system is adjusted to be adjacent to the voltage of the buck circuit module to overcome an input voltage difference.
  • a full range buck output voltage of a constant current illuminating diode between 85 Vac to 305 Vac is used for the luminescent diode unit.
  • the system includes an active power factor correction circuit to achieve high power factor values with low total harmonic distortion.
  • the system operates in a continuous power inductor critical mode and a metal oxide transistor operates in a zero power switching mode to reduce switching losses and increase inductor usage.
  • the system includes a cycle-by-cycle current limiting protection feature to protect a metal oxide transistor, inductor, and freewheeling diode to improve system reliability.
  • the system includes a floating ground wafer to isolate interference and prevent zero voltage and zero crossing effects to protect a metal oxide transistor, freewheeling diode, and the modules in the system.
  • Figure 1 shows a flow diagram of a modified circuit design and structure using a DC voltage mode to provide LEDs.
  • Figure 2 shows a block diagram of a modified circuit design and structure using a DC voltage mode to provide LEDs.
  • the present invention proposes a modified circuit design and structure that uses a DC voltage mode to provide a better power supply for the LED, which better improves power usage efficiency and full voltage (85Vac to 305Vac) input to overcome existing linear LEDs Design flaws in the driver IC.
  • Full voltage means that the incoming voltage is the actual voltage in the bulb, but when a resistor is used, for example, the incoming voltage is reduced and the actual voltage in the bulb is about 12V.
  • the full-voltage LED driver rectifies the AC full-wave waveform into an AC half-wave waveform via a bridge IC, and the system can use a step-down voltage circuit module that is implemented by MOS, pole, or electrical fusion.
  • the AC power source 101 is rectified into a DC power source for use as an LED.
  • the LED current limit is set by the MOS power transistor or step-down voltage setting module 103 because such a design overcomes the initial design flaws faced by conventional circuits.
  • the proposed system since the proposed system has a DC power supply corresponding to the LED unit 106 having a starting voltage using a DC power source, the efficiency of power use can be greatly improved.
  • the power usage improvement can be achieved by using the voltage sensing circuit module 104 to sense the voltage of the circuit; and using the buck voltage regulating module 105 to maintain a regulated voltage while maintaining a fixed output voltage and continuously The difference between the output and the regulated voltage is dissipated as waste heat.
  • Such circuits provide output voltage performance from less than 2V to greater than 100V, switching frequencies as large as 4MHz, and high efficiency operation up to 96%.
  • JF1606 is a high precision step-down LED constant current control wafer that is a step-down voltage circuit module 102 that includes a power factor adjustment module 110 for power factor adjustment.
  • the LED constant current control chip is suitable for a full range of buck input voltages with fixed current LEDs from 85Vac to 305Vac.
  • the system integrates active power factor correction circuitry to achieve high power factor and low total harmonic distortion. Since the MOS power transistor is in zero power switching mode due to operation in the continuous power inductor critical mode, switching losses are reduced and higher inductor usage is achieved. This improvement in power factor is achieved by adding a power factor correction capacitor to the distribution system. When apparent power (kVA) is greater than work Power (kW), the device must provide this excess reactive current plus the operating current.
  • the power capacitor acts as an inactive current generator.
  • the constant current controller (stable current, time independent current, fixed current) is a type of DC controller whose strength does not change with time. If the load is fixed, a steady current can be obtained by a fixed voltage source. If the load is variable, a steady current can be obtained by a fixed current supply.
  • the system has multiple protection functions to enhance system reliability, including: LED circuit protection module 111 for LED open circuit protection and / or LED short circuit protection; IC under voltage protection module 112 for protection with power supply under voltage IC or wafer; current sampling protection module 114 for protecting current sampling resistors on an open circuit; cycle-by-cycle power limiting module 116 to effectively protect the MOS field effect transistor, and allowing a current regulator or precision Simple configuration of current limit, etc. All protection modes have an automatic restart function.
  • the system also has a wafer thermal regulation protection 113 for reducing the output current when the drive power source is overheated to improve the reliability of the system.
  • the LED module includes: an LED power setting module 107 to determine the power applied by the LED unit 106; a power sensing circuit 108 to sense the power of the LED circuit; and an LED power adjuster 109 to maintain the pair of LED units A stable voltage of 106.
  • the proposed system for an LED driver is referred to as JF1606, and its block diagram is shown in Figure 2, which is an active power factor corrected LED constant current control wafer.
  • the system operates in a continuous power inductor critical mode, thus achieving extremely high power factor, extremely low total harmonic distortion and high efficiency.
  • the method of using the device as an LED driver includes the following steps.
  • the bus voltage is charged to the capacitor of the IC power supply pin (VCC) through the startup resistor.
  • VCC IC power supply pin
  • the device or system begins to output a pulse signal, and the Vref voltage gradually rises from 1.5V, and the peak current of the inductor rises accordingly, thereby achieving a soft start of the output LED current, effectively preventing the output current from overshooting.
  • the VCC voltage is supplied from the output voltage through the diode, thereby reducing power consumption.
  • the device or system then samples the inductor current cycle by cycle and operates in a continuous power inductor critical mode to achieve high precision output current control.
  • the LED output current calculation method is:
  • Vref is the internal reference reference voltage and Rcs is the current sampling resistance value
  • the device or system detects the state of the output voltage through a feedback network.
  • the buck threshold voltage of the feedback network is set at 0.2V and the hysteresis voltage is set to 0.15V.
  • the feedback network pin can also be used to detect Over Voltage Protection (OVP) with a threshold of 1.6V.
  • OVP Over Voltage Protection
  • the ratio of the upper and lower voltage divider resistors of the feedback network can be set to:
  • Rfbl is the lower divider resistor of the feedback network
  • Rfbh is the upper divider resistor of the feedback network
  • Vovp is the set point of the overvoltage protection
  • the divider resistor under the feedback network is recommended to be set at 5K ⁇ to 10K ⁇ . about.
  • the device or system is then connected to a thermal energy adjustment function.
  • the output current is gradually reduced, thereby controlling and maintaining the output power and temperature at a set value to improve the reliability of the system.
  • the thermal control point inside the wafer is set to 150 degrees Celsius.
  • the device or system is equipped with multiple built-in protection features to ensure system reliability.
  • the LED When the LED is open, the output voltage gradually rises, and the feedback network pin can detect the output voltage when the power transistor is turned off.
  • the protection logic When the feedback network rises to the OVP protection threshold, the protection logic is triggered and the switch is stopped.
  • the LED When the LED is short-circuited, since the output voltage is very low, VCC cannot be supplied through the diode, so the VCC voltage will gradually drop until VCC reaches the undervoltage protection threshold.
  • the system enters protection mode, the VCC voltage begins to drop, and when VCC reaches the undervoltage protection threshold, the system will restart. The system will continue the test and, once the fault is removed, the system will resume normal operation.
  • all isolated buck lines contain one or several transformers. By adjusting the turns ratio of the transformer, a higher or lower or negative potential output voltage can be obtained. In some isolated buck line configurations, multiple windings can be wound around the transformer to output multiple voltage values. Some converters also use transformers as energy storage devices, but other converters still require separate inductive devices. This type of power conversion mode is a "DC-AC-DC" conversion. However, this can be an expensive way.
  • the non-isolated power supply is the simplest power switch mode, and its power conversion mode is "DC-DC" conversion.
  • Boost Chopper also known as Boost Converter
  • Buck Chopper also known as buck
  • Buck-Boost Chopper also known as Buck-Boost Converter
  • Their structures are very similar, and the input, output, and grounding all meet at one point, using inductors for energy storage. The main difference between them is the way the inductor is connected. If the inductor is placed at the output of the circuit, it is a step-down chopper; when the inductor is placed at the input of the circuit, it is a boost chopper. When the inductor is grounded, it is a buck-boost chopper.
  • the full-voltage step-down LED constant current control chip receives the bridge half-wave waveform power, rectifies it into a DC power supply, and after LC filtering, supplies the power to the LED.
  • the LC circuit also referred to as a resonant circuit, a tank circuit, a tuning circuit
  • the LC circuit is an inductor (represented by the letter L) and a capacitor (represented by the letter C) connected to each other.
  • the full-voltage step-down LED constant current control chip is designed for ground landing, which uses a diode connection to control the floating ground of the wafer and the ground of the bridge IC, thereby isolating interference between the two parts and preventing The effect of zero voltage and zero crossing to protect the life of parts such as power MOS transistors and freewheeling diodes.

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Abstract

A system, for providing a starting voltage to a light emitting diode (LED) unit. The system comprises: a bridge module, for rectifying an AC full-wave waveform from a power source (101) into an AC half-wave waveform; and a step-down circuit module (102) having a metal oxide semiconductor, the step-down circuit module (102) being used for rectifying the AC half-wave waveform into a DC power supply for the LED unit (106). The step-down circuit module (102) corrects a power factor via a power factor correction module (110), and rectifies a full voltage by using a constant current control LED control chip, such that the DC power source (101) can receive the full voltage supplied to the LED unit (106) in a manner corresponding to the starting voltage of the LED unit (106).

Description

发光二极体Light-emitting diode 技术领域Technical field
本发明涉及一种用于一发光二极体(Light-Emitting Diode,LED)驱动器的装置。The present invention relates to an apparatus for a Light-Emitting Diode (LED) driver.
背景技术Background technique
LED驱动器为调整对一LED或多个LED的功率的装置。LED驱动器藉由在其电子特性随着温度改变时对LED提供一固定量的功率,可响应于LED或LED电路的需求改变。A LED driver is a device that adjusts the power to an LED or multiple LEDs. LED drivers can be responsive to the needs of LEDs or LED circuits by providing a fixed amount of power to the LEDs as their electronic characteristics change with temperature.
LED驱动器为一独立的电源,其具有对应于LED的电子特性的输出。LED驱动器可藉由脉宽调变电路的方法提供调光,以及可具有多于一个通道,以用于不同LED或LED阵列的分别控制。The LED driver is an independent power supply that has an output corresponding to the electronic characteristics of the LED. The LED driver can provide dimming by means of a pulse width modulation circuit and can have more than one channel for separate control of different LEDs or LED arrays.
借着由LED或多个LED所视的LED驱动器的随着温度的增加及减少的电子特性改变,LED的功率位准是由LED驱动器所固定地维持的。因此,在没有一适当的驱动器或系统,LED可能会过热或不稳,藉此表现不佳或失效。The LED power level is fixedly maintained by the LED driver by an increase in temperature and a decrease in electronic characteristics of the LED driver as viewed by the LED or LEDs. Therefore, without a suitable driver or system, the LEDs may overheat or become unstable, thereby performing poorly or failing.
现有的LED驱动器在对LED提供所需要的电源前,通常经过桥式积体电路(Integrated Circuit,IC)将交流(Alternating Current,AC)全波波形整流为AC半波波形。通常,LED的电流限制器是由金属氧化物半导体(Metal Oxide Semiconductor,MOS)功率电晶体所设定的。然而,这样的设计本身产生了两种问题,分别为功率损耗及输出电压差的问题。The existing LED driver rectifies an alternating current (AC) full-wave waveform into an AC half-wave waveform through a bridge integrated circuit (IC) before providing the required power to the LED. Typically, the current limiter of an LED is set by a Metal Oxide Semiconductor (MOS) power transistor. However, such a design itself creates two problems, namely power loss and output voltage difference.
功率损耗的问题是根据于采用AC半波波形的电源。当LED的启动电压为直流(Direct Current,DC)电源时,就会产生功率损耗。The problem of power loss is based on a power supply that uses an AC half-wave waveform. When the starting voltage of the LED is a direct current (DC) power supply, power loss occurs.
关于输出电压差的问题,既然Vin=Vf+Vds,在Vin增加而LED的Vf不变时,Vds将承受更大的电压差的功率,因而将造成MOS功率电晶体温度提高而最终烧毁。因此,此电路设计仅适用于单一电压装置的使用。Regarding the problem of the output voltage difference, since Vin=Vf+Vds, when Vin increases and the Vf of the LED does not change, Vds will withstand a larger voltage difference power, which will cause the MOS power transistor temperature to increase and eventually burn out. Therefore, this circuit design is only suitable for the use of a single voltage device.
因此,有必要改善功率的使用效率及全电压(85Vac至305Vac)输入,以克服目前线性LED驱动器的设计缺陷。 Therefore, it is necessary to improve the power efficiency and full voltage (85Vac to 305Vac) input to overcome the design flaws of current linear LED drivers.
发明内容Summary of the invention
本发明的一方面涉及一种系统,用于对一发光二极体单元提供一启动电压,该系统包括:一桥式模块,用于将来自一电源的一交流全波波形整流为一交流半波波形;一降压电路模块,具有一金属氧化物半导体,该降压电路模块用于将该交流半波波形整流为一用于该发光二极体单元的直流电源,其中,该降压电路模块藉由使用一功率因数调整模块以执行功率因数校正以及使用一定流控制发光二极体控制晶片以整流一全电压,以使该直流电源对应至该发光二极体单元的该启动电压的方式,可接收要提供至该发光二极体单元的该全电压。An aspect of the invention relates to a system for providing a starting voltage to a light emitting diode unit, the system comprising: a bridge module for rectifying an alternating current full wave waveform from a power source into an alternating current half a waveform circuit module having a metal oxide semiconductor, the step-down circuit module for rectifying the AC half-wave waveform into a DC power supply for the LED unit, wherein the step-down circuit The module uses a power factor adjustment module to perform power factor correction and uses a flow control LED to control the wafer to rectify a full voltage so that the DC power source corresponds to the startup voltage of the LED unit Receiving the full voltage to be supplied to the light emitting diode unit.
较佳地,该桥式模块为一桥积体电路。Preferably, the bridge module is a bridge circuit.
较佳地,该发光二极体单元为具有一积体电路的一发光二极体驱动器。Preferably, the light emitting diode unit is a light emitting diode driver having an integrated circuit.
较佳地,该发光二极体单元具有由一金属氧化物半导体功率电晶体所设定的一电流限制Preferably, the light emitting diode unit has a current limit set by a metal oxide semiconductor power transistor
较佳地,该系统的该电压被调整为邻近于该降压电路模块的电压,以克服一输入电压差。Preferably, the voltage of the system is adjusted to be adjacent to the voltage of the buck circuit module to overcome an input voltage difference.
较佳地,使用在85Vac至305Vac之间的定流发光二极体的全范围降压输出电压,以用于该发光二极体单元。Preferably, a full range buck output voltage of a constant current illuminating diode between 85 Vac to 305 Vac is used for the luminescent diode unit.
此外,该系统包括一有源功率因数校正电路,以达成具有低总谐波失真的高功率因数值。In addition, the system includes an active power factor correction circuit to achieve high power factor values with low total harmonic distortion.
较佳地,该系统工作于连续功率电感临界模式,以及一金属氧化物电晶体工作于零功率开关模式,以降低开关损耗以及增加电感使用。Preferably, the system operates in a continuous power inductor critical mode and a metal oxide transistor operates in a zero power switching mode to reduce switching losses and increase inductor usage.
此外,该系统包括一逐周期电流限制保护特征,以保护一金属氧化物电晶体、电感及续流二极体,以改善系统可靠性。In addition, the system includes a cycle-by-cycle current limiting protection feature to protect a metal oxide transistor, inductor, and freewheeling diode to improve system reliability.
此外,该系统包括一浮接地晶片,以隔离干扰及防止零电压及零交越的影响,以保护该系统中的一金属氧化物电晶体、续流二极体及该等模块。In addition, the system includes a floating ground wafer to isolate interference and prevent zero voltage and zero crossing effects to protect a metal oxide transistor, freewheeling diode, and the modules in the system.
本系统所包括的特征及各种组合将在以下以所附图式全部地说明。要理解的是,可在不脱离本发明的范围或牺牲本发明任何的优势的情况下,做出各样细节上的调整。The features and various combinations included in the system are fully described below in the drawings. It is to be understood that various modifications may be made without departing from the scope of the invention or the advantages of the invention.
附图说明 DRAWINGS
为了进一步阐明本发明的部分实施例的各方面,将参考所附图式,对特定的实施例进行本发明的更特定的说明。这些图式仅代表本发明的一典型实施例,且并不用于限制本发明的范围。本发明可藉由所附图式额外具体地跟详细地进行描述与说明。In order to further clarify aspects of some embodiments of the present invention, a more specific description of the invention will be made by way of the accompanying drawings. These drawings represent only a typical embodiment of the invention and are not intended to limit the scope of the invention. The invention may be described and illustrated in detail with particular reference to the drawings.
图1显示使用DC电压模式以提供LED的一修改电路设计及结构的流程图。Figure 1 shows a flow diagram of a modified circuit design and structure using a DC voltage mode to provide LEDs.
图2显示使用DC电压模式以提供LED的一修改电路设计及结构的方块图。Figure 2 shows a block diagram of a modified circuit design and structure using a DC voltage mode to provide LEDs.
其中,附图标记说明如下:Among them, the reference numerals are as follows:
101交流电源101 AC power supply
102降压电压电路模块102 step-down voltage circuit module
103降压电压设定模块103 step-down voltage setting module
104电压感测电路模块104 voltage sensing circuit module
105降压电压调整模块105 step-down voltage adjustment module
106发光二极体单元106 light emitting diode unit
107发光二极体功率设定模块107 LED power setting module
108功率感测电路108 power sensing circuit
109发光二极体功率调整器109 LED power regulator
110功率因数调整模块110 power factor adjustment module
111发光二极体电路保护模块111 light-emitting diode circuit protection module
112积体电路欠压保护模块112 integrated circuit undervoltage protection module
113晶片热能调节保护113 wafer thermal regulation protection
114电流采样保护模块114 current sampling protection module
115过压保护模块115 overvoltage protection module
116逐周期功率限制模块 116 cycle-by-cycle power limit module
具体实施方式detailed description
本发明提出一使用DC电压模式以提供LED更好的电源的的一修改电路设计及结构,其更好地改善功率的使用效率及全电压(85Vac至305Vac)输入,以克服现有的线性LED驱动器IC的设计缺陷。全电压指的是进入的电压是灯泡中实际的电压,但当使用电阻时,举例来说,进入的电压被降低且灯泡中实际的电压约为12V。The present invention proposes a modified circuit design and structure that uses a DC voltage mode to provide a better power supply for the LED, which better improves power usage efficiency and full voltage (85Vac to 305Vac) input to overcome existing linear LEDs Design flaws in the driver IC. Full voltage means that the incoming voltage is the actual voltage in the bulb, but when a resistor is used, for example, the incoming voltage is reduced and the actual voltage in the bulb is about 12V.
如图1所示,全电压LED驱动器会经过桥式IC将AC全波波形整流为AC半波波形,以及,该系统可使用藉由MOS、电杆或电融合所执行的降压电压电路模块102而将AC电源101整流成DC电源,以作为LED之使用。较佳地,该LED电流限制是由MOS功率电晶体或降压电压设定模块103所设定的,因为如此的设计可克服习知电路所面对的初始设计缺陷。关于功率损耗的第一个问题,因为提出的系统具有与LED单元106对应的DC电源,该LED单元106具有使用DC电源的启动电压,功率使用的效率可极大地改善。该功率使用改善可藉由以下方式达成:使用电压感测电路模块104以感测该电路的电压;以及使用降压电压调整模块105以维持一稳定电压,同时维持一固定输出电压且持续地将输出及调整电压之间的差异耗散为废热。这样的电路提供从小于2V到大于100V的输出电压性能、大至4MHz的开关频率及高达96%的高效率工作。As shown in Figure 1, the full-voltage LED driver rectifies the AC full-wave waveform into an AC half-wave waveform via a bridge IC, and the system can use a step-down voltage circuit module that is implemented by MOS, pole, or electrical fusion. 102, the AC power source 101 is rectified into a DC power source for use as an LED. Preferably, the LED current limit is set by the MOS power transistor or step-down voltage setting module 103 because such a design overcomes the initial design flaws faced by conventional circuits. Regarding the first problem of power loss, since the proposed system has a DC power supply corresponding to the LED unit 106 having a starting voltage using a DC power source, the efficiency of power use can be greatly improved. The power usage improvement can be achieved by using the voltage sensing circuit module 104 to sense the voltage of the circuit; and using the buck voltage regulating module 105 to maintain a regulated voltage while maintaining a fixed output voltage and continuously The difference between the output and the regulated voltage is dissipated as waste heat. Such circuits provide output voltage performance from less than 2V to greater than 100V, switching frequencies as large as 4MHz, and high efficiency operation up to 96%.
关于第二个问题(即,克服输入电压差),既然Vin=Vf+Vds,而Vin可在降压电压电路模块102调整至近于Vf电压,因而Vds将承受一更小的电压差的功率,因而MOS功率电晶体的寿命增长且可适用于全电压装置的使用。Regarding the second problem (ie, overcoming the input voltage difference), since Vin = Vf + Vds, and Vin can be adjusted to a voltage close to Vf at the step-down voltage circuit module 102, Vds will withstand a smaller voltage difference power, Thus the lifetime of the MOS power transistor is increased and can be applied to the use of full voltage devices.
用于LED驱动器的所提出系统被称为JF1606,JF1606为一种高精度降压型LED定流控制晶片,其为包括用于功率因数调整的功率因数调整模块110的降压电压电路模块102。该LED定流控制晶片适用于在85Vac至305Vac间的具有定流LED的全范围降压输入电压。本系统将有源功率因数校正电路集成,因此可以实现很高的功率因数以及很低的总谐波失真。由于工作在连续功率电感临界模式,MOS功率电晶体处于零功率开关模式,因此开关损耗得以减小,且会有更高的电感的使用率。该功率因数的改善由将功率因数校正电容增加至分配系统所达成的。当视在功率(kVA)大于工作 功率(kW),该设备必须提供该过多的无效电流加上该工作电流。功率电容作用为无效电流产生器。The proposed system for an LED driver is referred to as JF1606, which is a high precision step-down LED constant current control wafer that is a step-down voltage circuit module 102 that includes a power factor adjustment module 110 for power factor adjustment. The LED constant current control chip is suitable for a full range of buck input voltages with fixed current LEDs from 85Vac to 305Vac. The system integrates active power factor correction circuitry to achieve high power factor and low total harmonic distortion. Since the MOS power transistor is in zero power switching mode due to operation in the continuous power inductor critical mode, switching losses are reduced and higher inductor usage is achieved. This improvement in power factor is achieved by adding a power factor correction capacitor to the distribution system. When apparent power (kVA) is greater than work Power (kW), the device must provide this excess reactive current plus the operating current. The power capacitor acts as an inactive current generator.
该定流控制器(稳定电流、独立于时间的电流、固定电流)为一种DC控制器的类型,其强度并不随着时间改变。如果负载为固定的,一稳定电流可藉由一固定电压源所获得。如果负载为变化的,一稳定电流可藉由一固定电流供应源所获得。The constant current controller (stable current, time independent current, fixed current) is a type of DC controller whose strength does not change with time. If the load is fixed, a steady current can be obtained by a fixed voltage source. If the load is variable, a steady current can be obtained by a fixed current supply.
此外,本系统具有多重保护功能以加强系统可靠性,包括:LED电路保护模块111,以用于LED开路保护及/或LED短路保护;IC欠压保护模块112,以用于保护具有供电欠压的IC或晶片;电流采样保护模块114,以用于保护在一开路上的电流采样电阻;逐周期功率限制模块116,以有效地保护该MOS场效电晶体,以及允许定流调整器或精确的电流限制的简单配置等。所有的保护模式都具有自动重启功能。另外,本系统也具有晶片热能调节保护113,以用于在驱动电源过热时减小输出电流,以提高系统的可靠性。In addition, the system has multiple protection functions to enhance system reliability, including: LED circuit protection module 111 for LED open circuit protection and / or LED short circuit protection; IC under voltage protection module 112 for protection with power supply under voltage IC or wafer; current sampling protection module 114 for protecting current sampling resistors on an open circuit; cycle-by-cycle power limiting module 116 to effectively protect the MOS field effect transistor, and allowing a current regulator or precision Simple configuration of current limit, etc. All protection modes have an automatic restart function. In addition, the system also has a wafer thermal regulation protection 113 for reducing the output current when the drive power source is overheated to improve the reliability of the system.
此外,该LED模块包括:LED功率设定模块107,以判定LED单元106所适用的功率;功率感测电路108,以感测LED电路的功率;以及LED功率调整器109,以维持对LED单元106的一稳定电压。In addition, the LED module includes: an LED power setting module 107 to determine the power applied by the LED unit 106; a power sensing circuit 108 to sense the power of the LED circuit; and an LED power adjuster 109 to maintain the pair of LED units A stable voltage of 106.
所提出系统的额外特征包括:Additional features of the proposed system include:
-有源功率因数校正,高功率因数值,低总谐波失真- Active power factor correction, high power factor, low total harmonic distortion
-高达95%的系统效率- up to 95% system efficiency
-±3%LED输出电流精度-±3% LED output current accuracy
-优异的线电压调整率和负载调整率- Excellent line voltage regulation and load regulation
-连续功率电感临界模式- Continuous power inductor critical mode
-超低(30uA)启动电压- Ultra low (30uA) starting voltage
-LED短路/开路保护-LED short circuit / open circuit protection
-电流采样电阻开路保护- Current sampling resistor open circuit protection
-逐周期电源限制- Cycle-by-cycle power limit
-晶片电源欠压保护- Chip power supply undervoltage protection
-自动重启功能-Automatic restart function
-热能调节功能- Thermal regulation
所提出的系统中的LED单元106的应用包括: Applications of the LED unit 106 in the proposed system include:
-LED灯泡-LED bulb
-LED灯管-LED tube
-LED路灯-LED street light
-所有LED发光产品的电源- Power for all LED lighting products
<系统特征描述><System Feature Description>
用于LED驱动器的所提出系统被称为JF1606,其方块图如图2所示,其为一有源功率因数校正LED定流控制晶片。该系统工作于连续功率电感临界模式,因此实现极高的功率因数、极低的总谐波失真和高效率。The proposed system for an LED driver is referred to as JF1606, and its block diagram is shown in Figure 2, which is an active power factor corrected LED constant current control wafer. The system operates in a continuous power inductor critical mode, thus achieving extremely high power factor, extremely low total harmonic distortion and high efficiency.
使用该设备以作为LED驱动器的方法包括以下步骤。The method of using the device as an LED driver includes the following steps.
<1.系统启动><1. System startup>
在系统开启后,母线电压通过启动电阻给IC电源引脚(VCC)的电容充电。当VCC电压上升到启动阀值电压后,晶片内部控制电路开始工作,Vref电压被快速上拉到1.5V。After the system is turned on, the bus voltage is charged to the capacitor of the IC power supply pin (VCC) through the startup resistor. When the VCC voltage rises to the threshold voltage, the internal control circuit of the chip begins to operate and the Vref voltage is quickly pulled up to 1.5V.
然后该设备或系统开始输出脉冲信号,Vref电压从1.5V开始逐渐上升,电感峰值电流随的上升,从而实现输出LED电流的软启动,有效防止输出电流过冲。当输出电压建立之后,VCC电压由输出电压通过二极体供电,从而降低功耗。Then the device or system begins to output a pulse signal, and the Vref voltage gradually rises from 1.5V, and the peak current of the inductor rises accordingly, thereby achieving a soft start of the output LED current, effectively preventing the output current from overshooting. When the output voltage is established, the VCC voltage is supplied from the output voltage through the diode, thereby reducing power consumption.
<2.固定输出电流控制设定><2. Fixed output current control setting>
该设备或系统接着对电感电流进行逐周期采样,工作于连续功率电感临界模式,藉此实现高精度输出定流控制。LED输出电流计算方法为:The device or system then samples the inductor current cycle by cycle and operates in a continuous power inductor critical mode to achieve high precision output current control. The LED output current calculation method is:
Iout=Vref/RcsIout=Vref/Rcs
其中,Vref是内部基准参考电压,Rcs是电流采样电阻值Where Vref is the internal reference reference voltage and Rcs is the current sampling resistance value
<3.回馈网路><3. Feedback network>
该设备或系统通过回馈网路来检测输出电压的狀态,回馈网路的降压阀值电压设置在0.2V,迟滞电压设置为0.15V。回馈网路引脚也可以用来探测阀值为1.6V的过压保护(Over Voltage Protection,OVP)。回馈网路的上下分压电阻比例可以设置为:The device or system detects the state of the output voltage through a feedback network. The buck threshold voltage of the feedback network is set at 0.2V and the hysteresis voltage is set to 0.15V. The feedback network pin can also be used to detect Over Voltage Protection (OVP) with a threshold of 1.6V. The ratio of the upper and lower voltage divider resistors of the feedback network can be set to:
Rfbl/(Rfbl+Rfbh)=1.6V/VovpRfbl/(Rfbl+Rfbh)=1.6V/Vovp
其中,Rfbl是回馈网路的下分压电阻,Rfbh是回馈网路的上分压电阻,Vovp是过压保护的设定点,回馈网路下分压电阻建议设置在5KΩ至10KΩ 左右。Among them, Rfbl is the lower divider resistor of the feedback network, Rfbh is the upper divider resistor of the feedback network, Vovp is the set point of the overvoltage protection, and the divider resistor under the feedback network is recommended to be set at 5KΩ to 10KΩ. about.
<4.热能调节功能><4. Thermal energy adjustment function>
该设备或系统接着被连接至热能调节功能。当在驱动电源过热时,该输出电流被逐渐减少,从而控制及维持输出功率和温度在设定值,以提高系统的可靠性。晶片内部的过热控制点设定为摄氏150度。The device or system is then connected to a thermal energy adjustment function. When the driving power supply is overheated, the output current is gradually reduced, thereby controlling and maintaining the output power and temperature at a set value to improve the reliability of the system. The thermal control point inside the wafer is set to 150 degrees Celsius.
<5.保护功能><5. Protection function>
该设备或系统设置有多个内建保护功能,以保证系统可靠性。当LED开路时,输出电压逐渐上升,回馈网路引脚可以在功率电晶体关断时检测到输出电压。当回馈网路升高到OVP保护阀值时,会触发保护邏辑并停止开关工作。当LED短路时,由于输出电压很低,无法通过二极体给VCC供电,所以VCC电压会逐渐下降,一直到VCC达到欠压保护阀值。该系统进入保护模式时,VCC电压开始下降,而当VCC到达欠压保护阀值时,系统将重启。系统会持续该检测程序,以及,一旦故障解除,系统会重新开始正常工作。当输出短路或者变压器达到饱和状态时,共源极峰值电压值将会比较高。当共源极电压上升到内部值的限制(1V)时,该开关周期立刻停止。这样的逐周期电流限制功能可以保护功率MOS电晶体、电感以及续流二极体。The device or system is equipped with multiple built-in protection features to ensure system reliability. When the LED is open, the output voltage gradually rises, and the feedback network pin can detect the output voltage when the power transistor is turned off. When the feedback network rises to the OVP protection threshold, the protection logic is triggered and the switch is stopped. When the LED is short-circuited, since the output voltage is very low, VCC cannot be supplied through the diode, so the VCC voltage will gradually drop until VCC reaches the undervoltage protection threshold. When the system enters protection mode, the VCC voltage begins to drop, and when VCC reaches the undervoltage protection threshold, the system will restart. The system will continue the test and, once the fault is removed, the system will resume normal operation. When the output is shorted or the transformer is saturated, the common source peak voltage value will be higher. When the common source voltage rises to the internal value limit (1V), the switching cycle stops immediately. Such cycle-by-cycle current limiting functions protect power MOS transistors, inductors, and freewheeling diodes.
<电源的类型><Type of power supply>
<使用隔离型电源的实施例><Example of using isolated power supply>
通常,所有的隔离式降压线路都包含一个或数个变压器。通过调整变压器的匝数比,可获得更高或更低或是负电位的输出电压。在一些隔离式降压线路结构中,可在变压器上绕上多重绕组,以输出多种电压值。一些变换器还会利用变压器作为能量储存装置,但其他的变换器仍需要独立的电感装置。这类型的电源变换模式均为“直流-交流-直流”变换。然而,这会是一个昂贵的方式。Typically, all isolated buck lines contain one or several transformers. By adjusting the turns ratio of the transformer, a higher or lower or negative potential output voltage can be obtained. In some isolated buck line configurations, multiple windings can be wound around the transformer to output multiple voltage values. Some converters also use transformers as energy storage devices, but other converters still require separate inductive devices. This type of power conversion mode is a "DC-AC-DC" conversion. However, this can be an expensive way.
<使用非隔离型电源的另一实施例><Another embodiment of using a non-isolated power supply>
非隔离式电源是最为简单的电源开关模式,其电源变换方式为“直流-直流”变换。根据电压变换类型,分为三种基本类型:升压斩波器(Boost Chopper)(又称为升压变换器(Boost Converter));降压斩波器(Buck Chopper)(又称为降压变换器(Buck Converter));以及降压-升压斩波器(Buck-Boost Chopper)(又称为降压-升压变换器(Buck-Boost Converter))。 它们的结构都非常相似,输入、输出和接地都会在一点上交汇,都使用电感作为能量储存之用。它们之间的主要区别在于电感的连接方式,若电感器放置于电路的输出端,则为降压斩波器;电感放置于电路的输入端,则是升压斩波器。当电感器接地时,就是降压-升压斩波器。The non-isolated power supply is the simplest power switch mode, and its power conversion mode is "DC-DC" conversion. According to the type of voltage conversion, there are three basic types: Boost Chopper (also known as Boost Converter); Buck Chopper (also known as buck) Buck Converter (Buck-Boost Converter); and Buck-Boost Chopper (also known as Buck-Boost Converter). Their structures are very similar, and the input, output, and grounding all meet at one point, using inductors for energy storage. The main difference between them is the way the inductor is connected. If the inductor is placed at the output of the circuit, it is a step-down chopper; when the inductor is placed at the input of the circuit, it is a boost chopper. When the inductor is grounded, it is a buck-boost chopper.
在脉冲占空比极短时,开关装置的效率会下降。如果需要更高的电压变换,那就需要用到具有变压器的隔离型电源。When the pulse duty cycle is extremely short, the efficiency of the switching device is lowered. If a higher voltage conversion is required, then an isolated power supply with a transformer is required.
<使用全电压降压型LED定流控制晶片的再一实施例><Another embodiment of using a full voltage step-down type LED constant current control chip>
全电压降压型LED定流控制晶片接收到桥式半波波形功率、将其整流为DC电源,并经LC滤波后,将电源供应给LED使用。LC电路(又称为谐振电路、储能电路、调谐电路)为包括彼此连接的电感(由字母L所表示)及电容(由字母C所表示)。The full-voltage step-down LED constant current control chip receives the bridge half-wave waveform power, rectifies it into a DC power supply, and after LC filtering, supplies the power to the LED. The LC circuit (also referred to as a resonant circuit, a tank circuit, a tuning circuit) is an inductor (represented by the letter L) and a capacitor (represented by the letter C) connected to each other.
全电压降压型LED定流控制晶片设计为浮接地(ground landing),其使用二极体连接控制晶片的浮接地与桥式IC的地,藉此可隔离两个零件之间的干扰并防止零电压及零交越的影响,以保护功率MOS电晶体、续流二极体等零件的寿命。The full-voltage step-down LED constant current control chip is designed for ground landing, which uses a diode connection to control the floating ground of the wafer and the ground of the bridge IC, thereby isolating interference between the two parts and preventing The effect of zero voltage and zero crossing to protect the life of parts such as power MOS transistors and freewheeling diodes.
本发明可以在不脱离其必要特征下,以其他特定方式实施。所描述的实施例的所有方面皆应视为范例性且不具有局限性。因此,本发明的范围应以所附权利要求范围所定义,而非前述的说明。在权利要求范围的意义与等同范围内的变化皆应被接受为权利要求范围的范围。 The invention may be embodied in other specific forms without departing from the essential characteristics. All aspects of the described embodiments are to be considered as illustrative and not limiting. Therefore, the scope of the invention should be defined by the scope of the appended claims rather than the foregoing description. Variations within the meaning and range of the claims are intended to be embraced by the scope of the claims.

Claims (10)

  1. 一种系统,用于对一发光二极体单元提供一启动电压,其特征在于,该系统包括:A system for providing a starting voltage to a light emitting diode unit, the system comprising:
    一桥式模块,用于将来自一电源的一交流全波波形整流为一交流半波波形;a bridge module for rectifying an AC full-wave waveform from a power source into an AC half-wave waveform;
    一降压电路模块,具有一金属氧化物半导体,该降压电路模块用于将该交流半波波形整流为一用于该发光二极体单元的直流电源,a step-down circuit module having a metal oxide semiconductor, the step-down circuit module for rectifying the AC half-wave waveform into a DC power supply for the LED unit
    其中,该降压电路模块藉由使用一功率因数调整模块以执行功率因数校正以及使用一定流控制发光二极体控制晶片以整流一全电压,以使该直流电源对应至该发光二极体单元的该启动电压的方式,可接收要提供至该发光二极体单元的该全电压。Wherein, the step-down circuit module rectifies a full voltage by using a power factor adjustment module to perform power factor correction and using a flow control LED to control a full voltage so that the DC power source corresponds to the LED unit The manner of starting the voltage can receive the full voltage to be supplied to the light emitting diode unit.
  2. 根据权利要求1所述的系统,其特征在于,该桥式模块为一桥积体电路。The system of claim 1 wherein the bridge module is a bridge circuit.
  3. 根据权利要求1所述的系统,其特征在于,该发光二极体单元为具有一积体电路的一发光二极体驱动器。The system of claim 1 wherein the light emitting diode unit is a light emitting diode driver having an integrated circuit.
  4. 根据权利要求1所述的系统,其特征在于,该发光二极体单元具有由一金属氧化物半导体功率电晶体所设定的一电流限制The system of claim 1 wherein the light emitting diode unit has a current limit set by a metal oxide semiconductor power transistor
  5. 根据权利要求1所述的系统,其特征在于,该系统的该电压被调整为邻近于该降压电路模块的电压,以克服一输入电压差。The system of claim 1 wherein the voltage of the system is adjusted to be adjacent to a voltage of the buck circuit module to overcome an input voltage difference.
  6. 根据权利要求1所述的系统,其特征在于,使用在85Vac至305Vac之间的定流发光二极体的全范围降压输出电压,以用于该发光二极体单元。The system of claim 1 wherein a full range buck output voltage of a constant current illuminating diode between 85 Vac and 305 Vac is used for the luminescent diode unit.
  7. 根据权利要求1所述的系统,其特征在于,该功率因数调整模块具有一有源功率因数校正电路,以达成具有低总谐波失真的高功率因数值。The system of claim 1 wherein the power factor adjustment module has an active power factor correction circuit to achieve a high power factor value with low total harmonic distortion.
  8. 根据权利要求1所述的系统,其特征在于,该系统工作于连续连续功率电感临界模式,以及一金属氧化物电晶体工作于零功率开关模式,以降低开关损耗以及增加电感使用。The system of claim 1 wherein the system operates in a continuous continuous power inductor critical mode and a metal oxide transistor operates in a zero power switching mode to reduce switching losses and increase inductor usage.
  9. 根据权利要求1所述的系统,其特征在于,进一步包括一逐周期电流限制保护特征,以保护一金属氧化物电晶体、电感及续流二极体,以改善系 统可靠性。The system of claim 1 further comprising a cycle-by-cycle current limiting protection feature to protect a metal oxide transistor, inductor and freewheeling diode to improve the system System reliability.
  10. 根据权利要求1所述的系统,其特征在于,进一步包括一浮接地晶片,以隔离干扰及防止零电压及零交越的影响,以保护该系统中的一金属氧化物电晶体、续流二极体及该等模块。 The system of claim 1 further comprising a floating ground wafer to isolate interference and prevent zero voltage and zero crossing effects to protect a metal oxide transistor, freewheeling diode in the system Polar body and these modules.
PCT/CN2017/000383 2017-06-09 2017-06-09 Light emitting diode WO2018223247A1 (en)

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Citations (5)

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CN201846506U (en) * 2010-10-09 2011-05-25 大连森谷新能源电力技术有限公司 High efficiency light-emitting diode (LED) circuit driven by constant current source
CN103037576A (en) * 2012-11-29 2013-04-10 余姚亿威电子科技有限公司 LED constant current driving power supply circuit
CN104717787A (en) * 2013-12-17 2015-06-17 西安信唯信息科技有限公司 Small-size LED power supply
CN105578656A (en) * 2016-01-27 2016-05-11 张家港麦智电子科技有限公司 LED constant-current driving power supply with 120-347V AC wide input voltage range
JP6038190B2 (en) * 2013-01-29 2016-12-07 三菱電機株式会社 Power converter

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN201846506U (en) * 2010-10-09 2011-05-25 大连森谷新能源电力技术有限公司 High efficiency light-emitting diode (LED) circuit driven by constant current source
CN103037576A (en) * 2012-11-29 2013-04-10 余姚亿威电子科技有限公司 LED constant current driving power supply circuit
JP6038190B2 (en) * 2013-01-29 2016-12-07 三菱電機株式会社 Power converter
CN104717787A (en) * 2013-12-17 2015-06-17 西安信唯信息科技有限公司 Small-size LED power supply
CN105578656A (en) * 2016-01-27 2016-05-11 张家港麦智电子科技有限公司 LED constant-current driving power supply with 120-347V AC wide input voltage range

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