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参数资料
| 型号: | PFS726EG |
| 厂商: | Power Integrations |
| 文件页数: | 14/30页 |
| 文件大小: | 0K |
| 描述: | IC PFC CTLR 600W 180V ESIP |
| 标准包装: | 48 |
| 系列: | HiperPFS™ |
| 模式: | 连续导电(CCM) |
| 频率 - 开关: | 24kHz ~ 95kHz |
| 电源电压: | 10 V ~ 12 V |
| 工作温度: | -40°C ~ 125°C |
| 安装类型: | 通孔 |
| 封装/外壳: | 7-SIP,6 引线,裸露焊盘,成形引线 |
| 供应商设备封装: | eSIP-7G |
| 包装: | 管件 |
| 其它名称: | 596-1416 |
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�PFS704-729EG�
�V� CC�
�B+�
�When� the� above� component� values� are� used,� the� value� of�
�resistor� R1� can� be� calculated� using� the� equation� below:�
�D2�
�R1�
�R� 1� =�
�V� O� -� 79�
�100� #� 10� -� 6�
�R2�
�C1�
�Since� the� total� voltage� across� resistor� R1� is� approximately�
�301� V,� resistor� R1� may� have� to� be� divided� into� two� or� more�
�HiperPFS�
�D�
�V� VCC�
�CONTROL�
�FB�
�R8�
�Q1�
�R6�
�R3�
�resistors� to� distribute� the� voltage� stress� below� the� voltage�
�ratings� of� the� resistor� used.�
�The� value� of� resistor� R7� will� have� to� be� adjusted� in� some�
�designs� and� as� a� guideline� the� value� from� the� following�
�4� #� V� O� O�
�#� C�
�S�
�G�
�D1�
�R7�
�Q2�
�R4�
�calculation� can� be� used:�
�R� 7� =� R� Z� =�
�P� O�
�2�
�^� k� X� h�
�C3�
�C2�
�R5�
�PI-6228-111110�
�P� O�
�V� O�
�C� O�
�Maximum� continuous� output� power� in� watts�
�Nominal� PFC� output� voltage� in� volts�
�PFC� output� capacitance� in� farads�
�Figure� 14.� Recommended� Feedback� Circuit.�
�R7� and� capacitor� C2� is� the� loop� compensation� network� which�
�introduces� a� low� frequency� zero� required� to� tailor� the� loop�
�response� to� ensure� low� cross-over� frequency� and� sufficient�
�phase� margin.� Resistor� R6� isolates� the� fast� portion� (resistor�
�voltage� divider� network� comprising� of� resistors� R1� to� R5)� and�
�the� slow� feedback� loop� compensator� circuit� (resistor� R7� and�
�capacitor� C2).� Transistors� Q1� and� Q2,� biased� with� resistors� R3�
�and� R4� respectively,� detect� output� voltage� transient� conditions�
�and� provide� the� FEEDBACK� pin� with� “fast”� information� to�
�increase� the� loop� response� of� the� system.� Diode� D1� is� included�
�to� cover� a� single� point� fault� condition� wherein� capacitor� C2� is�
�shorted.� In� the� event� C2� is� short-circuited,� the� FEEDBACK� pin�
�is� forced� below� the� FB� OFF� threshold� through� diode� D1� and�
�subsequently� turns� the� HiperPFS� off.� Only� a� standard� recovery�
�diode� should� be� used� for� D1.� Use� of� ultrafast� or� fast� recovery�
�diode� is� not� recommended� including� small� signal� diodes� (e.g.�
�1N4148)� which� are� typically� also� fast� recovery.�
�The� recommended� values� for� the� components� used� are� as�
�follows:�
�R5� =� 57.6� k� W�
�R3,� R4� =� 2.2� k� W�
�R2� =� 732� k� W�
�C1� =� 0.1� m� F,� 100� V� X7R/NPO�
�R6� =� 160� k� W�
�R7� =� 3� k� W�
�R8� =� 2� k� W�
�C2� =� 4.7� m� F�
�C3� =� 10� nF� (For� layouts� that� result� in� excessive� noise� on� the�
�feedback� signal,� a� 20� nF� capacitor� may� be� used).�
�D1� =� BAV116� W� or� 1N4007� (A� general� purpose� standard�
�recovery� diode� should� only� be� used).�
�Q1,� Q2� =� Small� signal� transistors� equivalent� to� 2N4401� and�
�2N4403.�
�Improvement� in� low� frequency� phase� margin� can� be� achieved� by�
�increasing� the� value� of� the� capacitor� C2� however� increase� in� value�
�of� capacitor� C2� will� result� in� some� increase� in� overshoot� at� the�
�output� of� the� PFC� during� transient� loading� and� should� be� verified.�
�Diode� D2� connected� in� series� with� the� collector� of� the� NPN�
�transistor� Q1� is� to� prevent� loading� of� the� feedback� circuit� when�
�the� V� CC� is� absent.� Presence� of� this� diode� ensures� that� there� is�
�no� start-up� delay� when� the� V� CC� is� applied� to� the� HiperPFS,� the�
�feedback� circuit,� and� transistor.�
�Heat� Sinking� and� Thermal� Design�
�The� exposed� pad� on� the� HiperPFS� eSIP� package� is� internally�
�connected� to� the� drain� of� the� MOSFET.� Due� to� the� significant�
�amount� of� power� dissipated� in� the� part,� the� HiperPFS� should� be�
�mounted� on� a� rectangular� heat� spreader� made� of� thermally�
�conductive� material� such� as� Aluminum� or� Copper.� Figure� 15�
�shows� an� example� of� the� recommended� assembly� for� the�
�HiperPFS.� In� this� assembly� shown,� a� 0.76� mm� thick� aluminum�
�heat� spreader� is� used.� A� thermally� conductive� sil� pad� should� be�
�used� to� separate� the� heat� spreader� from� the� heat� sink.� A� thin�
�film� of� thermally� conductive� silicone� grease� should� be� applied� to�
�the� rear� surface� of� the� HiperPFS� to� ensure� low� thermal�
�resistance� contact� between� the� package� of� the� HiperPFS� and�
�the� heat� spreader.�
�For� universal� input� applications� up� to� 150� W� and� 230� VAC� only�
�applications� up� to� 300� W,� the� heat� spreader� is� not� essential.�
�Use� of� heat� spreader� in� these� applications� will� help� reduce�
�temperature� of� the� part� and� heat� spreaders� can� be� used� if�
�necessary.� Figure� 17� shows� an� example� of� the� recommended�
�assembly� for� lower� power� designs� that� do� not� need� a� heat�
�spreader.�
�The� HiperPFS� is� electrically� connected� to� the� heat� spreader� and�
�the� heat� sink� is� required� to� be� connected� to� the� source� in� order�
�to� reduce� EMI.� The� voltage� between� the� heat� spreader� and�
�heat� sink� can� easily� exceed� 400� V� during� transient� conditions.�
�Attention� should� be� placed� on� creepage� and� clearance� based�
�on� applicable� safety� specification.�
�14�
�Rev.� F� 12/12�
�www.powerint.com�
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相关代理商/技术参数 |
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| PFS727EG | 功能描述:功率因数校正 IC PFC w/ Pwr Mosfet 750 W MAX 180 VAC RoHS:否 制造商:Fairchild Semiconductor 开关频率:300 KHz 最大功率耗散: 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Reel |
| PFS728EG | 功能描述:功率因数校正 IC PFC w/ Pwr Mosfet 900 W MAX 180 VAC RoHS:否 制造商:Fairchild Semiconductor 开关频率:300 KHz 最大功率耗散: 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Reel |
| PFS729EG | 功能描述:功率因数校正 IC PFC w/ Pwr Mosfet 1000 W MAX 180 VAC RoHS:否 制造商:Fairchild Semiconductor 开关频率:300 KHz 最大功率耗散: 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Reel |
| PFS7323L | 功能描述:功率因数校正 IC HiPwr PFC Controller 120 W peak power RoHS:否 制造商:Fairchild Semiconductor 开关频率:300 KHz 最大功率耗散: 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Reel |
| PFS7324L | 功能描述:功率因数校正 IC HiPwr PFC Controller 150 W peak power RoHS:否 制造商:Fairchild Semiconductor 开关频率:300 KHz 最大功率耗散: 最大工作温度:+ 125 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Reel |
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