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参数资料
| 型号: | TOP270EG |
| 厂商: | Power Integrations |
| 文件页数: | 16/40页 |
| 文件大小: | 0K |
| 描述: | IC OFFLINE SW PWM OCP OVP 7ESIP |
| 特色产品: | TopSwitch?-JX Integrated Switcher Ics |
| 标准包装: | 48 |
| 输出隔离: | 隔离 |
| 频率范围: | 66 ~ 132kHz |
| 输出电压: | 725V |
| 功率(瓦特): | 140W |
| 工作温度: | -40°C ~ 150°C |
| 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-7C |
| 包装: | 管件 |
| 其它名称: | 596-1280-5 |
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�TOP264-271�
�Higher� current� rating,� low� V� F� Schottky� rectifier� diode� selected�
�TOPSwitch-JX MOSFET. This arrangement was selected over�
�a� standard� RCD� clamp� to� improve� light� load� efficiency� and� no-load�
�input� power.�
�In� a� standard� RCD� clamp� C4� would� be� discharged� by� a� parallel�
�resistor� rather� than� a� resistor� and� series� Zener.� In� an� RCD� clamp�
�the� resistor� value� is� selected� to� limit� the� peak� drain� voltage�
�under� full� load� and� overload� conditions.� However� under� light� or�
�no-load� conditions� this� resistor� value� now� causes� the� capacitor�
�voltage� to� discharge� significantly� as� both� the� leakage� inductance�
�energy� and� switching� frequency� are� lower.� As� the� capacitor� has�
�to� be� recharged� to� above� the� reflected� output� voltage� each�
�switching� cycle� the� lower� capacitor� voltage� represents� wasted�
�energy.� It� has� the� effect� of� making� the� clamp� dissipation�
�appear� as� a� significant� load� just� as� if� it� were� connected� to� the�
�output� of� the� power� supply.�
�The� RZCD� arrangement� solves� this� problem� by� preventing� the�
�voltage� across� the� capacitor� discharging� below� a� minimum�
�value� (defined� by� the� voltage� rating� of� VR2)� and� therefore�
�minimizing� clamp� dissipation� under� light� and� no-load� conditions.�
�Resistors� R6� and� R28� provide� damping� of� high� frequency�
�ringing� to� reduce� EMI.� Due� to� the� resistance� in� series� with� VR2,�
�limiting� the� peak� current,� standard� power� Zeners� vs� a� TVS� type�
�may� be� used� for� lower� cost� (although� a� TVS� type� was� selected�
�due� to� availability� of� a� SMD� version).� Diode� D2� was� selected� to�
�have� an� 800� V� vs� the� typical� 600� V� rating� due� to� its� longer�
�reverse� recovery� time� of� 500� ns.� This� allows� some� recovery� of�
�the� clamp� energy� during� the� reverse� recovery� time� of� the� diode�
�improving� efficiency.� Multiple� resistors� were� used� in� parallel� to�
�share� dissipation� as� SMD� components� were� used.�
�Feedback� Configuration�
�? � A� Darlington� connection� formed� together� with� optocoupler�
�transistor� to� reduce� secondary-side� feedback� current� and�
�therefore� no-load� input� power�
�? � Low� voltage,� low� current� voltage� reference� IC� used� on�
�secondary-side� to� reduce� secondary-side� feedback� current�
�and� therefore� no-load� input� power�
�? � Bias� winding� voltage� tuned� to� ~9� V� at� no-load,� high-line� to�
�reduce� no-load� input� power�
�Typically� the� feedback� current� into� the� CONTROL� pin� at� high�
�line� is� ~3� mA.� This� current� is� both� sourced� from� the� bias�
�winding� (voltage� across� C10)� and� directly� from� the� output.� Both�
�of� these� represent� a� load� on� the� output� of� the� power� supply.�
�16�
�Rev.� E� 08/12�
�To� minimize� the� dissipation� from� the� bias� winding� under� no-load�
�conditions� the� number� of� bias� winding� turns� and� value� of� C10�
�was� adjusted� to� give� a� minimum� voltage� across� C10� of� ~9� V.�
�This� is� the� minimum� required� to� keep� the� optocoupler� biased.�
�To� minimize� the� dissipation� of� the� secondary-side� feedback�
�circuit� Q2� was� added� to� form� a� Darlington� connection� with� U3B.�
�This� reduced� the� feedback� current� on� the� secondary� to� ~1� mA.�
�The� increased� loop� gain� (due� to� the� h� FE� of� the� transistor)� was�
�compensated� by� increasing� the� value� of� R16� and� the� addition� of�
�R25.� A� standard� 2.5� V� TL431� voltage� reference� was� replaced�
�with� the� 1.24� V� LMV431� to� reduce� the� supply� current� requirement�
�from� 1� mA� to� 100� m� A.�
�Output� Rectifier� Choice�
�? �
�for� output� rectifier�
�A� dual� 15� A,� 100� V� Schottky� rectifier� diode� with� a� V� F� of� 0.455� V�
�at� 5� A� was� selected� for� D5.� This� is� a� higher� current� rating� than�
�required� to� reduce� resistive� and� forward� voltage� losses� to� improve�
�both� full� load� and� average� efficiency.� The� use� of� a� 100� V� Schottky�
�was� possible� due� to� the� high� transformer� primary� to� secondary�
�turns� ratio� (V� OR� =� 110� V)� which� was� in� turn� possible� due� to� the�
�high-voltage� rating� of� the� TOPSwitch-JX� internal� MOSFET.�
�Increased� Output� Overvoltage� Shutdown� Sensitivity�
�? � Transistor� Q1� and� VR1� added� to� improve� the� output� over-�
�voltage� shutdown� sensitivity�
�During� an� open� loop� condition� the� output� and� therefore� bias�
�winding� voltage� will� rise.� When� this� exceeds� the� voltage� of� VR1�
�plus� a� V� BE� voltage� drop� Q1� turns� on� and� current� is� fed� into� the�
�V� pin.� The� addition� of� Q1� ensures� that� the� current� into� the� V� pin�
�is� sufficient� to� exceed� the� latching� shutdown� threshold� even�
�when� the� output� is� fully� loaded� while� the� supply� is� operating� at�
�low-line� as� under� this� condition� the� output� voltage� overshoot� is�
�relatively� small�
�Output� overload� power� limitation� is� provided� via� the� current� limit�
�programming� feature� of� the� X� pin� and� R7,� R8� and� R9.� Resistors�
�R8� and� R9� reduce� the� device� current� limit� as� a� function� of�
�increasing� line� voltage� to� provide� a� roughly� flat� overload� power�
�characteristic,� below� the� 100� VA� limited� power� source� (LPS)�
�requirement.� In� order� to� still� meet� this� under� a� single� fault�
�condition� (such� as� open� circuit� of� R8)� the� rise� in� the� bias� voltage�
�that� occurs� during� an� overload� condition� is� also� used� to� trigger�
�a� latching� shutdown.�
�www.powerint.com�
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相关代理商/技术参数 |
参数描述 |
|---|---|
| TOP270EG/VG | 制造商:POWERINT 制造商全称:Power Integrations, Inc. 功能描述:Integrated Off-Line Switcher with EcoSmart Technology for Highly Efficient Power Supplies |
| TOP270EG-TL | 制造商:POWERINT 制造商全称:Power Integrations, Inc. 功能描述:Integrated Off-Line Switcher with EcoSmart Technology for Highly Efficient Power Supplies |
| TOP270KG | 功能描述:交流/直流开关转换器 Int Off-Line Switchr EcoSmart,60W/91W RoHS:否 制造商:STMicroelectronics 输出电压:800 V 输入/电源电压(最大值):23.5 V 输入/电源电压(最小值):11.5 V 开关频率:115 kHz 电源电流:1.6 mA 工作温度范围:- 40 C to + 150 C 安装风格:SMD/SMT 封装 / 箱体:SSO-10 封装:Reel |
| TOP270KG-TL | 功能描述:交流/直流开关转换器 Int Off-Line Switchr EcoSmart,60W/91W RoHS:否 制造商:STMicroelectronics 输出电压:800 V 输入/电源电压(最大值):23.5 V 输入/电源电压(最小值):11.5 V 开关频率:115 kHz 电源电流:1.6 mA 工作温度范围:- 40 C to + 150 C 安装风格:SMD/SMT 封装 / 箱体:SSO-10 封装:Reel |
| TOP270VG | 功能描述:交流/直流开关转换器 Int Off-Line Switchr 140W/190W RoHS:否 制造商:STMicroelectronics 输出电压:800 V 输入/电源电压(最大值):23.5 V 输入/电源电压(最小值):11.5 V 开关频率:115 kHz 电源电流:1.6 mA 工作温度范围:- 40 C to + 150 C 安装风格:SMD/SMT 封装 / 箱体:SSO-10 封装:Reel |
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