参数资料
| 型号: | LNK501P |
| 厂商: | Power Integrations |
| 文件页数: | 9/20页 |
| 文件大小: | 0K |
| 描述: | IC SWIT OCP CV/CC HV 8DIP |
| 标准包装: | 3,000 |
| 系列: | LinkSwitch® |
| 输出隔离: | 隔离 |
| 频率范围: | 26kHz ~ 46kHz |
| 输出电压: | 700V |
| 功率(瓦特): | 4W |
| 工作温度: | -40°C ~ 150°C |
| 封装/外壳: | 8-DIP(0.300",7.62mm),7 引线 |
| 供应商设备封装: | DIP-8B |
| 包装: | 管件 |
| 配用: | 596-1001-ND - KIT DESIGN ACCELERATOR ADAPTER |
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�
�LNK501�
�At� very� light� or� no-load,� typically� less� than� 2� mA� of� output� current,�
�the� output� voltage� rises� due� to� leakage� inductance� peak� charging�
�of� the� secondary.� This� voltage� rise� can� be� reduced� with� a� small�
�preload� with� little� change� to� no-load� power� consumption.�
�The� output� voltage� load� variation� can� be� improved� across� the�
�whole� load� range� by� adding� an� optocoupler� and� secondary�
�reference� (Figure� 6).� The� secondary� reference� is� designed� to� only�
�provide� feedback� above� the� normal� peak� power� point� voltage�
�to� maintain� the� correct� constant� current� characteristic.�
�Component� Selection�
�The� schematic� shown� in� Figure� 5� outlines� the� key� components�
�needed� for� a� LinkSwitch� supply.�
�Clamp� diode� –� D1�
�Diode� D1� should� be� either� a� fast� (t� rr� <250� ns)� or� ultra-fast�
�type� (t� rr� <50� ns),� with� a� voltage� rating� of� 600� V� or� higher.� Fast�
�recovery� types� are� preferred,� being� typically� lower� cost.� Slow�
�diodes� are� not� recommended;� they� can� allow� excessive� DRAIN�
�ringing� and� the� LinkSwitch� to� be� reverse� biased.�
�Clamp� Capacitor� –� C2�
�Capacitor� C2� should� be� a� 0.1� μ� F,� 100� V� capacitor.� Low� cost�
�metallized� plastic� ?lm� types� are� recommended.� The� tolerance�
�of� this� part� has� a� very� minor� effect� on� the� output� characteristic�
�so� any� of� the� standard� ±5%,� ±10%� or� ±20%� tolerances� are�
�acceptable.� Ceramic� capacitors� are� not� recommended.� The�
�common� dielectrics� used� such� as� Y5U� or� Z5U� are� not� stable�
�with� voltage� or� temperature� and� may� cause� output� instability.�
�Ceramic� capacitors� with� high� stability� dielectrics� may� be� used�
�but� are� expensive� compared� to� metallized� ?lm� types.�
�CONTROL� Pin� Capacitor� –� C1�
�Capacitor� C1� is� used� during� start-up� to� power� LinkSwitch� and�
�sets� the� auto-restart� frequency.� For� designs� that� have� a� battery�
�load� this� component� should� have� a� value� of� 0.22� μ� F� and� for�
�resistive� loads� a� value� of� 1� μ� F.� This� ensures� there� is� suf?cient�
�time� during� start-up� for� the� output� voltage� to� reach� regulation.�
�Any� capacitor� type� is� acceptable� with� a� voltage� rating� of�
�10� V� or� above.�
�Feedback� Resistor� –� R1�
�The� value� of� R1� is� selected� to� give� a� feedback� current� into� the�
�CONTROL� pin� of� approximately� 2.3� mA� at� the� peak� output�
�power� point� of� the� supply.� The� actual� value� depends� on� the� V� OR�
�selected� during� design.� Any� 1%,� 0.25� W� resistor� is� suitable.�
�Output� Diode� –� D2�
�Either� PN� fast,� PN� ultra-fast� or� Schottky� diodes� can� be� used�
�depending� on� the� ef?ciency� target� for� the� supply,� Schottky�
�diodes� giving� higher� ef?ciency� then� PN� diodes.� The� diode�
�voltage� rating� should� be� suf?cient� to� withstand� the� output�
�voltage� plus� the� input� voltage� transformed� through� the� turns�
�ratio� (a� typical� V� OR� of� 50� V� requires� a� diode� PIV� of� 50� V).�
�Slow� recovery� diodes� are� not� recommended� (1N400X� types).�
�Output� Capacitor� –� C4�
�Capacitor� C4� should� be� selected� such� that� its� voltage� and� ripple�
�current� speci?cations� are� not� exceeded.�
�LinkSwitch� Layout� considerations�
�Primary� Side� Connections�
�Since� the� SOURCE� pins� in� a� LinkSwitch� supply� are� switching�
�nodes,� the� copper� area� connected� to� SOURCE� together� with� C1,�
�C2� and� R1� (Figure� 5)� should� be� minimized,� within� the� thermal�
�contraints� of� the� design,� to� reduce� EMI� coupling.�
�The� CONTROL� pin� capacitor� C1� should� be� located� as� close� as�
�possible� to� the� SOURCE� and� CONTROL� pins.�
�To� minimize� EMI� coupling� from� the� switching� nodes� on� the�
�primary� to� both� the� secondary� and� AC� input,� the� LinkSwitch�
�should� be� positioned� away� from� the� secondary� of� the� transformer�
�and� AC� input.�
�Routing� the� primary� return� trace� from� the� transformer� primary�
�around� LinkSwitch� and� associated� components� further� reduces�
�coupling.�
�Y� capacitor�
�If� a� Y� capacitor� is� required,� it� should� be� connected� close� to� the�
�transformer� secondary� output� return� pin(s)� and� the� primary� bulk�
�capacitor� negative� return.� Such� placement� will� maximize� the�
�EMI� bene?t� of� the� Y� capacitor� and� avoid� problems� in� common-�
�mode� surge� testing.�
�Quick� Design� Checklist�
�As� with� any� power� supply� design,� all� LinkSwitch� designs�
�should� be� veri?ed� on� the� bench� to� make� sure� that� component�
�speci?cations� are� not� exceeded� under� worst� case� conditions.�
�Note:� In� a� LinkSwitch� circuit,� the� SOURCE� is� a� switching�
�node.� This� should� be� taken� into� consideration� during� testing.�
�Oscilloscope� measurements� should� be� made� with� probe� grounded�
�to� DC� voltages� such� as� primary� return� or� DC� rail� but� not� to�
�SOURCE.� Power� supply� input� voltage� should� always� be� supplied�
�using� an� isolation� transformer.� The� following� minimum� set� of�
�tests� is� strongly� recommended:�
�1.� Maximum� drain� voltage� –� Verify� that� V� DS� does� not� exceed�
�675� V� at� highest� input� voltage� and� peak� output� power.�
�2.� Maximum� drain� current� –� At� maximum� ambient� temperature,�
�maximum� input� voltage� and� peak� output� power,� verify� drain�
�current� waveforms� at� start-up� for� any� signs� of� transformer�
�saturation� and� excessive� leading� edge� current� spikes.�
�LinkSwitch� has� a� minimum� leading� edge� blanking� time� of�
�I�
�2/05�
�9�
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相关代理商/技术参数 |
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| LNK501P_1 | 制造商:POWERINT 制造商全称:Power Integrations, Inc. 功能描述:2.2W Cell Phone Charger |
| LNK501PN | 功能描述:交流/直流开关转换器 3W 85-265 VAC 4W 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 |
| LNK520 | 制造商:POWERINT 制造商全称:Power Integrations, Inc. 功能描述:Energy Efficient, CV or CV/CC Switcher for Very Low Cost Adapters and Chargers |
| LNK520G | 功能描述:IC SWIT OCP CV/CC HV 8SMD RoHS:否 类别:集成电路 (IC) >> PMIC - AC-DC 转换器,离线开关 系列:LinkSwitch® 标准包装:1 系列:FPS™ 输出隔离:隔离 频率范围:61kHz ~ 73kHz 输入电压:8 V ~ 26 V 输出电压:650V 功率(瓦特):12W 工作温度:-40°C ~ 115°C 封装/外壳:8-DIP(0.300",7.62mm) 供应商设备封装:8-MDIP 包装:Digi-Reel® 其它名称:FSL206MRBNFSDKR |
| LNK520GN | 功能描述:交流/直流开关转换器 3W 85-265 VAC 4W 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 |
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