- 您现在的位置:买卖IC网 > PDF目录19748 > TNY279GN (Power Integrations)IC OFFLINE SWIT OVP OTP HV 8SMD PDF资料下载
参数资料
| 型号: | TNY279GN |
| 厂商: | Power Integrations |
| 文件页数: | 10/24页 |
| 文件大小: | 0K |
| 描述: | IC OFFLINE SWIT OVP OTP HV 8SMD |
| 标准包装: | 50 |
| 系列: | TinySwitch®-III |
| 输出隔离: | 隔离 |
| 频率范围: | 124kHz ~ 140kHz |
| 输出电压: | 700V |
| 功率(瓦特): | 32W |
| 工作温度: | -40°C ~ 150°C |
| 封装/外壳: | 8-SMD(7 个接脚),鸥形翼 |
| 供应商设备封装: | SMD-8C |
| 包装: | 管件 |
| 配用: | 596-1194-ND - KIT DESIGN REF TINYSWITCH-III |
��
�
�TNY274-280�
�value� (10� Ω� to� 47� Ω� )� resistor� in� series� with� the� bias� winding�
�diode� and/or� the� OVP� Zener� as� shown� by� R7� and� R3� in�
�Figure� 14.� The� resistor� in� series� with� the� OVP� Zener� also� limits�
�the� maximum� current� into� the� BP/M� pin.�
�Reducing� No-load� Consumption�
�As� TinySwitch-III� is� self-powered� from� the� BP/M� pin� capacitor,�
�there� is� no� need� for� an� auxillary� or� bias� winding� to� be� provided�
�on� the� transformer� for� this� purpose.� Typical� no-load�
�consumption� when� self-powered� is� <150� mW� at� 265� VAC� input.�
�The� addition� of� a� bias� winding� can� reduce� this� down� to� <50� mW�
�by� supplying� the� TinySwitch-III� from� the� lower� bias� voltage� and�
�inhibiting� the� internal� high� voltage� current� source.� To� achieve�
�this,� select� the� value� of� the� resistor� (R8� in� Figure� 14)� to� provide�
�the� data� sheet� DRAIN� supply� current.� In� practice,� due� to� the�
�reduction� of� the� bias� voltage� at� low� load,� start� with� a� value�
�equal� to� 40%� greater� than� the� data� sheet� maximum� current,�
�and� then� increase� the� value� of� the� resistor� to� give� the� lowest� no-�
�load� consumption.�
�capacitor,� transformer� primary� and� TinySwitch-III� together�
�should� be� kept� as� small� as� possible.�
�Primary� Clamp� Circuit�
�A� clamp� is� used� to� limit� peak� voltage� on� the� DRAIN� pin� at� turn�
�off.� This� can� be� achieved� by� using� an� RCD� clamp� or� a� Zener�
�(~200� V)� and� diode� clamp� across� the� primary� winding.� In� all�
�cases,� to� minimize� EMI,� care� should� be� taken� to� minimize� the�
�circuit� path� from� the� clamp� components� to� the� transformer� and�
�TinySwitch-III.�
�Thermal� Considerations�
�The� four� SOURCE� pins� are� internally� connected� to� the� IC� lead�
�frame� and� provide� the� main� path� to� remove� heat� from� the�
�device.� Therefore� all� the� SOURCE� pins� should� be� connected� to�
�a� copper� area� underneath� the� TinySwitch-III� to� act� not� only� as� a�
�single� point� ground,� but� also� as� a� heatsink.� As� this� area� is�
�connected� to� the� quiet� source� node,� this� area� should� be�
�maximized� for� good� heatsinking.� Similarly� for� axial� output�
�diodes,� maximize� the� PCB� area� connected� to� the� cathode.�
�Audible� Noise�
�The� cycle� skipping� mode� of� operation� used� in� TinySwitch-III� can�
�generate� audio� frequency� components� in� the� transformer.� To�
�limit� this� audible� noise� generation� the� transformer� should� be�
�designed� such� that� the� peak� core� ?ux� density� is� below�
�3000� Gauss� (300� mT).� Following� this� guideline� and� using� the�
�standard� transformer� production� technique� of� dip� varnishing�
�practically� eliminates� audible� noise.� Vacuum� impregnation� of�
�the� transformer� should� not� be� used� due� to� the� high� primary�
�capacitance� and� increased� losses� that� result.� Higher� ?ux�
�densities� are� possible,� however� careful� evaluation� of� the� audible�
�noise� performance� should� be� made� using� production�
�transformer� samples� before� approving� the� design.�
�Ceramic� capacitors� that� use� dielectrics� such� as� Z5U,� when�
�used� in� clamp� circuits,� may� also� generate� audio� noise.� If� this� is�
�the� case,� try� replacing� them� with� a� capacitor� having� a� different�
�dielectric� or� construction,� for� example� a� ?lm� type.�
�TinySwitch-lll� Layout� Considerations�
�Layout�
�See� Figure� 15� for� a� recommended� circuit� board� layout� for�
�TinySwitch-III.�
�Single� Point� Grounding�
�Use� a� single� point� ground� connection� from� the� input� ?lter�
�capacitor� to� the� area� of� copper� connected� to� the� SOURCE� pins.�
�Bypass� Capacitor� (C� BP� )�
�The� BP/M� pin� capacitor� should� be� located� as� near� as� possible�
�to� the� BP/M� and� SOURCE� pins.�
�EN/UV� Pin�
�Keep� traces� connected� to� the� EN/UV� pin� short� and,� as� far� as� is�
�practical,� away� from� all� other� traces� and� nodes� above� source�
�potential� including,� but� not� limited� to,� the� BYPASS� and� DRAIN�
�pins.�
�Primary� Loop� Area�
�The� area� of� the� primary� loop� that� connects� the� input� ?lter�
�10�
�Rev.� I� 01/09�
�Y-Capacitor�
�The� placement� of� the� Y-capacitor� should� be� directly� from� the�
�primary� input� ?lter� capacitor� positive� terminal� to� the� common/�
�return� terminal� of� the� transformer� secondary.� Such� a� placement�
�will� route� high� magnitude� common� mode� surge� currents� away�
�from� the� TinySwitch-III� device.� Note� –� if� an� input� π� (C,� L,� C)� EMI�
�?lter� is� used� then� the� inductor� in� the� ?lter� should� be� placed�
�between� the� negative� terminals� of� the� input� ?lter� capacitors.�
�Optocoupler�
�Place� the� optocoupler� physically� close� to� the� TinySwitch-III� to�
�minimizing� the� primary-side� trace� lengths.� Keep� the� high�
�current,� high� voltage� drain� and� clamp� traces� away� from� the�
�optocoupler� to� prevent� noise� pick� up.�
�Output� Diode�
�For� best� performance,� the� area� of� the� loop� connecting� the�
�secondary� winding,� the� output� diode� and� the� output� ?lter�
�capacitor,� should� be� minimized.� In� addition,� suf� ?cient� copper�
�area� should� be� provided� at� the� anode� and� cathode� terminals� of�
�the� diode� for� heatsinking.� A� larger� area� is� preferred� at� the� quiet�
�cathode� terminal.� A� large� anode� area� can� increase� high�
�frequency� radiated� EMI.�
�PC� Board� Leakage� Currents�
�TinySwitch-III� is� designed� to� optimize� energy� ef� ?ciency� across�
�the� power� range� and� particularly� in� standby/no-load� conditions.�
�Current� consumption� has� therefore� been� minimized� to� achieve�
�this� performance.� The� EN/UV� pin� undervoltage� feature� for�
�example� has� a� low� threshold� (~1� μ� A)� to� detect� whether� an�
�undervoltage� resistor� is� present.�
�Parasitic� leakage� currents� into� the� EN/UV� pin� are� normally� well�
�below� this� 1� μ� A� threshold� when� PC� board� assembly� is� in� a� well�
�controlled� production� facility.� However,� high� humidity�
�conditions� together� with� board� and/or� package� contamination,�
�either� from� no-clean� ?ux� or� other� contaminants,� can� reduce� the�
�surface� resistivity� enough� to� allow� parasitic� currents� >1� μ� A� to�
�?ow� into� the� EN/UV� pin.� These� currents� can� ?ow� from� higher�
�voltage� exposed� solder� pads� close� to� the� EN/UV� pin� such� as�
�www.powerint.com�
�相关PDF资料 |
PDF描述 |
|---|---|
| MIC29202BU TR | IC REG LDO ADJ .4A TO-263-5 |
| HMC36DRTN | CONN EDGECARD 72POS DIP .100 SLD |
| TAJC685M025RNJ | CAP TANT 6.8UF 25V 20% 2312 |
| HMC36DRTH | CONN EDGECARD 72POS DIP .100 SLD |
| LCMXO2280E-4T144C | IC PLD 2280LUTS 113I/O 144-TQFP |
相关代理商/技术参数 |
参数描述 |
|---|---|
| TNY279GN0152-TL | 制造商:Power Integrations 功能描述: |
| TNY279GN-TL | 功能描述:交流/直流开关转换器 25W 85-265 VAC 32W/230 VAC 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 |
| TNY279GTL | 制造商:POWERINT 制造商全称:Power Integrations, Inc. 功能描述:Energy Efficient, Off-Line Switcher with Enhanced Flexibility and Extended Power Range |
| TNY279P | 制造商:POWERINT 制造商全称:Power Integrations, Inc. 功能描述:Energy Efficient, Off-Line Switcher with Enhanced Flexibility and Extended Power Range |
| TNY279PG | 功能描述:交流/直流开关转换器 25 W (85-265 VAC) 32 W (230 VAC) 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 |
发布紧急采购,3分钟左右您将得到回复。