参数资料
| 型号: | MC33364D2G |
| 厂商: | ON Semiconductor |
| 文件页数: | 9/16页 |
| 文件大小: | 0K |
| 描述: | IC CTRLR SMPS OTP UVLO 8SOIC |
| 标准包装: | 98 |
| 系列: | GreenLine™ |
| 输出隔离: | 隔离 |
| 频率范围: | 104kHz ~ 800kHz |
| 输入电压: | 8.5 V ~ 16 V |
| 输出电压: | 700V |
| 工作温度: | -25°C ~ 125°C |
| 封装/外壳: | 8-SOIC(0.154",3.90mm 宽) |
| 供应商设备封装: | 8-SOICN |
| 包装: | 管件 |
| 其它名称: | MC33364D2GOS |
��
�
�MC33364�
�APPLICATION� INFORMATION�
�Design� Example�
�Design� an� off--line� Flyback� converter� according� to� the�
�following� requirements:�
�Output� Power:� 12� W�
�Output:� 6.0� V� @� 2� Amperes�
�Input� voltage� range:� 90� Vac� --� 270� Vac,� 50/60� Hz�
�The� operation� for� the� circuit� shown� in� Figure� 12� is� as�
�follows:� the� rectifier� bridge� D1--D4� and� the� capacitor� C1�
�convert� the� ac� line� voltage� to� dc.� This� voltage� supplies� the�
�primary� winding� of� the� transformer� T1� and� the� startup�
�circuit� in� U1� through� the� line� pin.� The� primary� current� loop�
�is� closed� by� the� transformer� ’s� primary� winding,� the� TMOS�
�startup� switch� is� turned� off� by� the� undervoltage� and� the�
�overvoltage� control� circuit.� Because� the� power� supply� can�
�be� shorted� on� the� output,� causing� the� auxiliary� voltage� to� be�
�zero,� the� MC33364� will� periodically� start� its� startup� block.�
�This� mode� is� named� “hiccup� mode”.� During� this� mode� the�
�temperature� of� the� chip� rises� but� remains� protected� by� the�
�thermal� shutdown� block.� During� the� power� supply’s� normal�
�operation,� the� high� voltage� internal� MOSFET� is� turned� off,�
�preventing� wasted� power,� and� thereby,� allowing� greater�
�circuit� efficiency.�
�Since� a� bridge� rectifier� is� used,� the� resulting� minimum� and�
�maximum� dc� input� voltages� can� be� calculated:�
�switch� Q1� and� the� current� sense� resistor� R7.� The� resistors�
�R5,� R6,� diode� D6� and� capacitor� C4� create� a� snubber�
�V�
�in(min)�
�dc� =� ?� 2� xV�
�in(min)�
�ac� =� ?� ?� 2� ?� ?� 90� Vac� ?� =� 127� V�
�clamping� network� that� protects� Q1� from� spikes� on� the�
�primary� winding.� The� network� consisting� of� capacitor� C3,�
�V�
�in(� m� ax)�
�dc� =� ?� 2� xV�
�in(� m� ax)�
�ac� =� ?� ?� 2� ?� ?� 270� Vac� ?� =� 382� V�
�P� out� 12� W�
�in�
�nV�
�0.8� ?� 127� V� ?�
�in(max)�
�flbk�
�TMOS�
�in(min)�
�flbk�
�127� V�
�flbk�
�[127� V� +� 127� V]�
�?� max� =� =� =� 0.5�
�in(min)�
�flbk�
�in� =� 2.0� ?� 0.118� A� ?� =� 0.472� A�
�ppk�
�?� max�
�0.5�
�diode� D5� and� resistor� R1� provides� a� V� CC� supply� voltage� for�
�U1� from� the� auxiliary� winding� of� the� transformer.� The�
�resistor� R1� makes� V� CC� more� stable� and� resistant� to� noise.�
�The� resistor� R2� reduces� the� current� flow� through� the� internal�
�clamping� and� protection� zener� diode� of� the� Zero� Crossing�
�Detector� (ZCD)� within� U1.� C3� is� the� decoupling� capacitor�
�of� the� supply� voltage.� The� resistor� R3� can� provide� additional�
�bias� current� for� the� optoisolator� ’s� transistor.� The� diode� D8�
�and� the� capacitor� C5� rectify� and� filter� the� output� voltage.� The�
�TL431,� a� programmable� voltage� reference,� drives� the�
�primary� side� of� the� optoisolator� to� provide� isolated� feedback�
�to� the� MC33364.� The� resistor� divider� consisting� of� R10� and�
�R11� program� the� voltage� of� the� TL431.� The� resistor� R9� and�
�the� capacitors� C7� and� C8� provide� frequency� compensation�
�of� the� feedback� loop.� Resistor� R8� provides� a� current� limit� for�
�the� opto� coupler� and� the� TL431.�
�Since� the� critical� conduction� mode� converter� is� a� variable�
�frequency� system,� the� MC33364� has� a� built--in� special� block�
�to� reduce� switching� frequency� in� the� no� load� condition.� This�
�block� is� named� the� ”frequency� clamp”� block.� MC33364�
�used� in� the� design� example� has� an� internal� frequency� clamp�
�set� to� 126� kHz.� However,� optional� versions� with� a� disabled�
�or� variable� frequency� clamp� are� available.� The� frequency�
�clamp� works� as� follows:� the� clamp� controls� the� part� of� the�
�switching� cycle� when� the� MOSFET� switch� is� turned� off.� If�
�this� ”off--time”� (determined� by� the� reset� time� of� the�
�transformer� ’s� core)� is� too� short,� then� the� frequency� clamp�
�does� not� allow� the� switch� to� turn--on� again� until� the� defined�
�frequency� clamp� time� is� reached� (i.e.,� the� frequency� clamp�
�will� insert� a� dead� time).�
�There� are� several� advantages� of� the� MC33364’s� startup�
�circuit.� The� startup� circuit� includes� a� special� high� voltage�
�switch� that� controls� the� path� between� the� rectified� line�
�voltage� and� the� V� CC� supply� capacitor� to� charge� that�
�capacitor� by� a� limited� current� when� the� power� is� applied� to�
�the� input.� After� a� few� switching� cycles� the� IC� is� supplied�
�from� the� transformer� ’s� auxiliary� winding.� After� V� CC�
�reaches� the� undervoltage� lockout� threshold� value,� the�
�The� maximum� average� input� current� is:�
�I� =� =� =� 0.118� A�
�in(min)�
�where� n� =� estimated� circuit� efficiency.�
�A� TMOS� switch� with� 600� V� avalanche� breakdown�
�voltage� is� used.� The� voltage� on� the� switch’s� drain� consists� of�
�the� input� voltage� and� the� flyback� voltage� of� the�
�transformer� ’s� primary� winding.� There� is� a� ringing� on� the�
�rising� edge’s� top� of� the� flyback� voltage� due� to� the� leakage�
�inductance� of� the� transformer.� This� ringing� is� clamped� by� the�
�RCD� network.� Design� this� clamped� wave� for� an� amplitude�
�of� 50� V� below� the� avalanche� breakdown� of� the� TMOS�
�device.� Add� another� 50� V� to� allow� a� safety� margin� for� the�
�MOSFET.� Then� a� suitable� value� of� the� flyback� voltage� may�
�be� calculated:�
�V� =� V� ?� V� ?� 100� V�
�=� 600� V� ?� 382� V� ?� 100� V� =� 118� V�
�Since� this� value� is� very� close� to� the� V� in(min)� ,� set:�
�V� =� V� =� 127� V�
�The� V� flbk� value� of� the� duty� cycle� is� given� by:�
�V�
�V� +� V�
�The� maximum� input� primary� peak� current:�
�2I�
�I� =�
�Choose� the� desired� minimum� frequency� f� min� of� operation�
�to� be� 70� kHz.�
�After� reviewing� the� core� sizing� information� provided� by�
�a� core� manufacturer,� a� EE� core� of� size� about� 20� mm� was�
�chosen.� Siemens’� N67� magnetic� material� is� used,� which�
�corresponds� to� a� Philips� 3C85� or� TDK� PC40� material.�
�http://onsemi.com�
�9�
�相关PDF资料 |
PDF描述 |
|---|---|
| MC33385DHR2 | IC SWITCH QUAD L-SIDE 20-HSOP |
| MC33470DWR2G | IC CONV DC/DC SYNC RECT 20-SOIC |
| MC33580BAPNAR2 | IC SW QUAD HI SIDE 15MOHM 24PQFN |
| MC33761SNT1-050G | IC REG LDO 5V 80MA 5TSOP |
| MC33874BPNAR2 | IC SW QUAD HI SIDE 35MOHM 24PQFN |
相关代理商/技术参数 |
参数描述 |
|---|---|
| MC33364D2R2 | 功能描述:电流型 PWM 控制器 Variable Frequency RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
| MC33364D2R2G | 功能描述:电流型 PWM 控制器 Variable Frequency SMPS RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
| MC33364DG | 功能描述:电流型 PWM 控制器 Variable Frequency SMPS RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
| MC33364DR2 | 功能描述:电流型 PWM 控制器 Variable Frequency RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
| MC33364DR2G | 功能描述:电流型 PWM 控制器 Variable Frequency SMPS RoHS:否 制造商:Texas Instruments 开关频率:27 KHz 上升时间: 下降时间: 工作电源电压:6 V to 15 V 工作电源电流:1.5 mA 输出端数量:1 最大工作温度:+ 105 C 安装风格:SMD/SMT 封装 / 箱体:TSSOP-14 |
发布紧急采购,3分钟左右您将得到回复。