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参数资料
| 型号: | NCL30001DR2G |
| 厂商: | ON Semiconductor |
| 文件页数: | 18/31页 |
| 文件大小: | 0K |
| 描述: | IC ANA PFC CONTROLLER 16SOIC |
| 产品培训模块: | NCL30000 |
| 标准包装: | 1 |
| 恒定电流: | 是 |
| 拓扑: | 回扫,PWM,降压(降压) |
| 输出数: | 1 |
| 内部驱动器: | 无 |
| 类型 - 主要: | 通用 |
| 频率: | 20kHz ~ 250kHz |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 16-SOIC(0.154",3.90mm 宽) |
| 供应商设备封装: | 16-SOIC |
| 包装: | 标准包装 |
| 其它名称: | NCL30001DR2GOSDKR |
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�NCL30001�
�DETAILED� DEVICE� DESCRIPTION�
�Introduction�
�The� NCL30001� is� a� highly� integrated� controller�
�combining� PFC� and� isolated� step� down� power� conversion� in�
�a� single� stage,� resulting� in� a� lower� cost� and� reduced� part�
�count� solution.� This� controller� is� ideal� for� LED� Lighting�
�applications� with� power� requirements� between� 40� W� and�
�150� W� with� an� output� voltage� greater� than� 12� V.� The� single�
�stage� is� based� on� the� flyback� converter� and� it� is� designed� to�
�components.� But,� because� it� processes� the� power� twice,� the�
�search� is� always� on� for� a� more� compact� and� power� efficient�
�solution.�
�The� NCL30001� controller� offers� the� convenience� of�
�shrinking� the� front� ?� end� converter� (PFC� preregulator)� and�
�the� dc� ?� dc� converter� into� a� single� power� processing� stage� as�
�shown� in� Figure� 46.�
�operate� in� CCM� mode.�
�Power� Factor� Correction� (PFC)� Introduction�
�Power� factor� correction� shapes� the� input� current� of�
�AC�
�Input�
�Rectifier�
�&�
�Filter�
�NCL30001� Based�
�Single� ?� Stage�
�Flyback� Converter�
�V� out�
�off� ?� line� power� supplies� to� maximize� the� real� power�
�available� from� the� mains.� Ideally,� the� electrical� appliance�
�should� present� a� load� that� emulates� a� pure� resistor,� in� which�
�case� the� reactive� power� drawn� by� the� device� is� zero.� Inherent�
�in� this� scenario� is� the� freedom� from� input� current� harmonics.�
�The� current� is� a� perfect� replica� of� the� input� voltage� (usually�
�a� sine� wave)� and� is� exactly� in� phase� with� it.� In� this� case� the�
�current� drawn� from� the� mains� is� at� a� minimum� for� the� real�
�power� required� to� perform� the� needed� work,� and� this�
�minimizes� losses� and� costs� associated� not� only� with� the�
�distribution� of� the� power,� but� also� with� the� generation� of� the�
�power� and� the� capital� equipment� involved� in� the� process.�
�The� freedom� from� harmonics� also� minimizes� interference�
�with� other� devices� being� powered� from� the� same� source.�
�Another� reason� to� employ� PFC� in� many� of� today’s� power�
�supplies� is� to� comply� with� regulatory� requirements.� Today,�
�lighting� equipment� in� Europe� must� comply� with�
�IEC61000� ?� 3� ?� 2� Class� C.� This� requirement� applies� to� most�
�lighting� applications� with� input� power� of� 25� W� or� greater,�
�and� it� specifies� the� maximum� amplitude� of� line� ?� frequency�
�harmonics� up� to� and� including� the� 39� th� harmonic.� Moreover�
�power� factor� requirements� for� commercial� lighting� is�
�included� within� the� ENERGY� STAR� ?� Solid� State� Lighting�
�Luminaire� standard� regardless� of� the� applications� power�
�level.�
�Typical� Power� Supply� with� PFC�
�A� typical� power� supply� consists� of� a� boost� PFC�
�preregulator� creating� an� intermediate� X� 400� V� bus� and� an�
�isolated� dc� ?� dc� converter� producing� the� desired� output�
�voltage� as� shown� in� Figure� 45.� This� architecture� has� two�
�power� stages.�
�Figure� 46.� Single� Stage� Power� Converter�
�This� approach� significantly� reduces� the� component� count.�
�The� NCL30001� based� solution� requires� only� one� each� of�
�MOSFET,� magnetic� element,� output� rectifier� (low� voltage)�
�and� output� capacitor� (low� voltage).� In� contrast,� the� 2� ?� stage�
�solution� requires� two� or� more� of� the� above� ?� listed�
�components.� Elimination� of� certain� high� ?� voltage�
�components� (e.g.� high� voltage� capacitor� and� high� voltage�
�PFC� diode)� has� significant� impact� on� the� system� design.� The�
�resultant� cost� savings� and� reliability� improvement� are� often�
�worth� the� effort� of� designing� a� new� converter.�
�Single� PFC� Stage�
�While� the� single� stage� offers� certain� benefits,� it� is�
�important� to� recognize� that� it� is� not� a� recommended� solution�
�for� all� requirements.� The� following� three� limitations� apply�
�to� the� single� stage� approach:�
�?� The� output� voltage� ripple� will� have� a� 2x� line� frequency�
�component� (120� Hz� for� North� American� applications)�
�that� can� not� be� eliminated� easily.� The� cause� of� this�
�ripple� is� the� elimination� of� the� energy� storage� element�
�that� is� typically� the� boost� output� capacitor� in� the�
�2� ?� stage� solution.� The� only� way� to� reduce� the� ripple� is� to�
�increase� the� output� filter� capacitance.� The� required�
�value� of� capacitance� is� inversely� proportional� to� the�
�output� voltage.� Normally� the� presence� of� this� ripple� is�
�not� a� issue� for� most� LED� lighting� applications.�
�?� The� hold� ?� up� time� will� not� be� as� good� as� the� 2� ?� stage�
�approach� –� again� due� to� the� lack� of� an� intermediate�
�AC�
�Input�
�Rectifier�
�&�
�Filter�
�PFC�
�Preregulator�
�DC� ?� DC�
�Converter�
�with� isolation�
�V� out�
�energy� storage� element.�
�?� In� a� single� stage� converter,� one� FET� processes� all� the�
�power� –� that� is� both� a� benefit� and� a� limitation� as� the�
�stress� on� that� main� MOSFET� is� relatively� higher.�
�Similarly,� the� magnetic� component� (flyback�
�Figure� 45.� Typical� Two� Stage� Power� Converter�
�A� two� stage� architecture� allows� optimization� of� each�
�individual� power� stage.� It� is� commonly� used� because� of�
�designer� familiarity� and� a� vast� range� of� available�
�transformer/inductor)� can� not� be� optimized� as� well� as� in�
�the� 2� ?� stage� solution.� As� a� result,� potentially� higher�
�leakage� inductance� induces� higher� voltage� spikes� (like�
�the� one� shown� in� Figure� 47)� on� the� MOSFET� drain.�
�This� may� require� a� MOSFET� with� a� higher� voltage�
�http://onsemi.com�
�18�
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