参数资料
| 型号: | HIP4082EVAL |
| 厂商: | Intersil |
| 文件页数: | 4/13页 |
| 文件大小: | 0K |
| 描述: | EVAL BOARD FET DRIVER HIP4082 |
| 标准包装: | 1 |
| 类型: | FET 驱动器 |
| 适用于相关产品: | HIP4082 |
| 所含物品: | 完全组装的评估板 |
��
�
�Application� Note� 9611�
�with� the� additional� trace� impedances� in� the� bootstrap�
�charging� loop� will� not� allow� 24A� to� flow.� Often� the� customer’s�
�power� supply� used� for� biasing� the� driver� and� control� logic� is�
�incapable� of� supplying� this� magnitude� of� current.� For� this�
�reason,� much� larger� bypass� capacitors� are� recommended�
�for� the� V� CC� supply� than� are� used� for� the� bootstrap�
�capacitors.� A� good� rule� of� thumb� is� ten� times� greater.� In� the�
�example� above,� if� the� bootstrap� circuit� impedance� is�
�estimated� to� be� about� 5� ?� ,� then� the� peak� current� will� be� only�
�2.4A.� The� time� required� to� charge� up� the� bootstrap� capacitor�
�(an� exponential� charge� characteristic� is� assumed)� to� just�
�under� 11V� will� be� approximately� 12� μ� s.� (24� times� the� charge�
�time� allotted� by� default� within� the� IC!)� To� avoid� problems�
�when� driving� large� MOSFETs� or� when� paralleling� MOSFETs�
�it� is� necessary� to� consider� the� low� voltage� bias� supply’s�
�output� impedance,� the� bias� supply’s� bypass� capacitor�
�(located� at� the� HIP4082� IC),� the� size� of� the� bootstrap�
�capacitor� (it� should� also� be� about� 10� times� the� equivalent�
�input� capacitance� of� the� connected� MOSFETs),� and� the�
�forward� resistance� characteristic� of� the� chosen� bootstrap�
�diode.�
�Transformer� Specification�
�Current� Product-to-Market� needs� often� require� having� a�
�magnetics� supplier� design� the� magnetics� devices� in� your�
�design.� We� followed� this� approach� with� respect� to� the� eval-�
�board’s� transformer� and� choke.� The� electronics� designer�
�provides� a� detailed� specification� to� the� transformer� supplier.�
�The� specification� should� include� the� minimum� frequency� of�
�operation,� the� maximum� applied� voltage� and� waveform,� the�
�continuous� and� overload� current� profiles,� and� operating�
�ambient� temperature.� Required� transformer� regulation� must�
�also� be� specified.� The� transformer� designer� needs� to� know�
�this� in� order� to� size� the� transformer� wire� and� leakage�
�inductance.� The� power� handling� capability� and� operating�
�frequency� influences� choice� of� core� size� and� geometry� and�
�ultimately� the� cost� and� size� of� the� transformer.� (Refer� to� the�
�Bill� of� Material� included� in� the� Appendix� for� information�
�regarding� the� transformer.)�
�It� is� important� that� the� transformer� designer� have� knowledge�
�of� the� transformer� excitation� waveform.� The� reason� that� this�
�is� important� is� that� the� current� waveshape� dictates� the� form�
�factor� or� the� value� of� RMS� (root-mean-square)� current� that�
�will� result� for� a� given� required� average� current.� The� size� of�
�the� filter� capacitor,� the� equivalent� series� impedance� of� the�
�secondary,� and� the� output� voltage� waveshape� will� determine�
�the� current� waveform� and� form� factor.� The� RMS� current�
�determines� the� power� losses� in� the� transformer� and�
�temperature� rise.� To� minimize� ringing� on� the� inverter� bridge�
�of� the� primary� inverter� it� will� help� to� minimize� the� leakage�
�inductance� of� the� transformer.� For� the� DC-to-AC� inverter�
�eval-board,� power� ferrite� material,� E� core� style� PQ3230,� was�
�used� for� the� core.�
�In� order� to� minimize� transformer� size� and� maximize� winding�
�fill,� the� primary� was� formed� of� 3� separate� windings� which� were�
�paralleled� to� supply� the� approximately� 30A� RMS� required� at�
�rated� output� power.� Each� primary� winding’s� DC� resistance� is�
�less� than� 10m� ?� .� There� are� two� equal,� but� separate,�
�secondary� power� output� windings.� When� series-connected,�
�these� secondary� power� output� windings� provide� 230V� AC� load�
�power.� The� US� configured� eval-boards� are� provided� with�
�paralleled� output� windings� for� 115V� AC� operation.� Series�
�connection� via� soldered� jumper� wires� allows� for� 230V� AC�
�operation,� but� this� shouldn’t� be� attempted� without� changing�
�the� power� MOSFETs� and� the� voltage� ratings� of� several�
�capacitors.� A� 500V� MOSFET� with� an� r� DS(ON)� of� 1.5� ?� such� as�
�the� Intersil� IRF830R� would� be� a� suitable� device� for� 230V� AC�
�operation.� Besides� having� to� double� the� capacitor� voltage�
�ratings� of� C� 23� ,� C� 27� and� C� 13� ,� the� capacity� of� C� 23� and� C� 27� will�
�have� to� be� dropped� by� a� factor� of� 4.� This� maintains� the� power�
�dissipation� in� resistors,� R� 34� and� R� 38� to� remain� as� they� are� for�
�the� 115V� AC� design.�
�A� third� secondary� winding� provides� low� voltage� control�
�power� to� all� of� the� secondary-side� inverter� logic� and� gate�
�drivers.� This� voltage� is� nominally� 20.5V� (peak� of� the� square-�
�wave)� when� there� is� a� nominal� 13.6V� DC� applied� to� the�
�battery� input� terminals� of� the� eval-board.� This� winding� must�
�output� at� least� 14V� at� the� minimum� battery� voltage� in� order�
�to� keep� the� series� regulator� out� of� saturation.� This� winding�
�carries� less� than� 100mA,� so� winding� gauge� will� be�
�determined� more� for� strength� than� for� current� carrying�
�capacity.�
�Secondary� Inverter� Design�
�The� secondary-side� inverter� and� control� is� designed� to�
�provide� a� near� constant� 115V� AC� to� 120V� AC� ,� 55Hz� output�
�voltage� waveform.� The� inverter� can� supply� approximately�
�120W� to� loads� such� as� small� fans,� lights,� radios� and� other�
�small� electric� appliances� that� might� be� handy� to� have� with�
�you� on� a� camping� trip,� for� example.�
�In� addition,� a� simple� current� trip� circuit� and� an� overtemp�
�limiter� was� incorporated� in� order� to� provide� features� similar�
�to� a� commercially� available� DC-to-AC� inverter� of� similar�
�rating� and� purpose.�
�The� secondary-side� inverter� includes� the� following� functions:�
�?� A� high� voltage� input� rectifier� and� filter�
�?� A� high� voltage� DC-to-AC� inverter� and� control� circuits,�
�providing� over-current,� thermal� protection,� and� output�
�voltage� regulation� to� compensate� for� widely� varying�
�battery� voltages� and� output� current;�
�?� A� neon� lamp� to� warn� of� the� presence� of� high� voltage� and�
�ELECTRICAL� SHOCK� HAZARD� .� Details� of� these� circuits�
�follow.�
�Input� Filter� and� Rectifiers�
�There� are� two� full� wave� rectifiers.� One� rectifies� the� 162V�
�secondary� voltage� to� provide� the� DC� high� voltage� bus� for� the�
�4�
�相关PDF资料 |
PDF描述 |
|---|---|
| HIP4086EVAL | EVALUATION BOARD GP HIP4086 |
| HIP6004EVAL1 | EVALUATION BOARD HIP6004 |
| HIP6500BEVAL1 | EVALUATION BOARD HIP6500 |
| HIP6501AEVAL1 | EVALUATION BOARD ACPI HIP6501 |
| HIP9011EVAL1Z | BOARD EVALUATION FOR HIP9011 |
相关代理商/技术参数 |
参数描述 |
|---|---|
| HIP4082IB | 功能描述:功率驱动器IC 80V H BRDG FET DRVR RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
| HIP4082IBS2599 | 制造商:Intersil Corporation 功能描述: |
| HIP4082IBT | 功能描述:功率驱动器IC TAPE & VER OF STDARD HIP4082IB RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
| HIP4082IBTS2457 | 制造商:Intersil Corporation 功能描述: |
| HIP4082IBZ | 功能描述:功率驱动器IC 80V H BRDG FET DRVR RoHS:否 制造商:Micrel 产品:MOSFET Gate Drivers 类型:Low Cost High or Low Side MOSFET Driver 上升时间: 下降时间: 电源电压-最大:30 V 电源电压-最小:2.75 V 电源电流: 最大功率耗散: 最大工作温度:+ 85 C 安装风格:SMD/SMT 封装 / 箱体:SOIC-8 封装:Tube |
发布紧急采购,3分钟左右您将得到回复。