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参数资料
| 型号: | ISL6142CB-T |
| 厂商: | Intersil |
| 文件页数: | 18/23页 |
| 文件大小: | 0K |
| 描述: | IC CONTROLLER HOT PLUG 14-SOIC |
| 标准包装: | 2,500 |
| 类型: | 热交换控制器 |
| 应用: | 通用型 VoIP |
| 内部开关: | 无 |
| 电源电压: | 36 V ~ 72 V |
| 工作温度: | 0°C ~ 70°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 14-SOIC(0.154",3.90mm 宽) |
| 供应商设备封装: | 14-SOICN |
| 包装: | 带卷 (TR) |
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�ISL6142,� ISL6152�
�the� hard� fault� comparator� trip� point� is� exceeded,� a� hard� pull�
�down� current� (350mA)� is� enabled� to� quickly� pull� down� the�
�GATE� and� momentarily� turn� off� the� FET.� The� fast� shutdown�
�resets� the� timer� and� is� followed� by� a� soft� start,� single� retry�
�event.� If� the� fault� is� still� present� after� the� GATE� is� slowly�
�turned� on,� the� current� limit� regulator� will� trip� (sense� pin�
�voltage� >� 50mV),� turn� on� the� timer,� and� limit� the� current� to�
�50mV/Rsense.� If� the� fault� remains� and� the� time-out� period� is�
�exceeded� the� GATE� pin� will� be� latched� low.� Note:� Since� the�
�timer� starts� when� the� SENSE� pin� exceeds� the� 50mV�
�threshold,� then� depending� on� the� speed� of� the� current�
�transient� exceeding� 200mV;� it’s� possible� that� the� current� limit�
�time-out� and� shutdown� can� occur� before� the� hard� fault�
�comparator� trips� (and� thus� no� retry).� Figure� 33� illustrates� the�
�hard� fault� response� with� a� zero� ohm� short� circuit� at� the� output.�
�FIGURE� 33.� HARD� FAULT� SHUTDOWN� AND� RETRY�
�As� in� the� Over-Current� Time-Out� response� discussed�
�previously,� the� supply� is� set� at� -48V� and� the� current� limit� is�
�set� at� 2.5A.� After� the� initial� gate� shutdown� (10μs)� a� soft-start�
�is� initiated� with� the� short� circuit� still� present.� As� the� GATE�
�slowly� turns� on� the� current� ramps� up� and� exceeds� the�
�Over-Current� threshold� (50mV)� enabling� the� timer� and�
�current� limiting� (2.5A).� The� fault� remains� for� the� duration� of�
�the� time-out� period� and� the� GATE� pin� is� quickly� pulled� low�
�and� latched� off.�
�Applications:� OV� and� UV�
�The� UV� and� OV� pins� can� be� used� to� detect� Over-Voltage�
�and� Under-Voltage� conditions� on� the� input� supply� and�
�quickly� shut� down� the� external� FET� to� protect� the� system.�
�Each� pin� is� tied� to� an� internal� comparator� with� a� nominal�
�reference� of� 1.255V.� A� resistor� divider� between� the� V� DD�
�(gnd)� and� -V� IN� is� typically� used� to� set� the� trip� points� on� the�
�UV� and� OV� pins.� If� the� voltage� on� the� UV� pin� is� above� its�
�threshold� and� the� voltage� on� the� OV� pin� is� below� its�
�threshold,� the� supply� is� within� its� expected� operating� range�
�18�
�and� the� GATE� will� be� allowed� to� turn� on,� or� remain� on.� If� the�
�UV� pin� voltage� drops� below� its� high� to� low� threshold,� or� the�
�OV� pin� voltage� increases� above� its� low� to� high� threshold,� the�
�GATE� pin� will� be� pulled� low,� turning� off� the� FET� until� the�
�supply� is� back� within� tolerance.�
�The� OV� and� UV� inputs� are� high� impedance,� so� the� value� of�
�the� external� resistor� divider� is� not� critical� with� respect� to� input�
�current.� Therefore,� the� next� consideration� is� total� current;� the�
�resistors� will� always� draw� current,� equal� to� the� supply�
�voltage� divided� by� the� total� resistance� of� the� divider�
�(R4+R5+R6)� so� the� values� should� be� chosen� high� enough� to�
�get� an� acceptable� current.� However,� to� the� extent� that� the�
�noise� on� the� power� supply� can� be� transmitted� to� the� pins,� the�
�resistor� values� might� be� chosen� to� be� lower.� A� filter� capacitor�
�from� UV� to� -V� IN� or� OV� to� -V� IN� is� a� possibility,� if� certain�
�transients� need� to� be� filtered.� (Note� that� even� some�
�transients� which� could� momentarily� shut� off� the� GATE� might�
�recover� fast� enough� such� that� the� GATE� or� the� output�
�current� does� not� even� see� the� interruption).�
�Finally,� take� into� account� whether� the� resistor� values� are�
�readily� available,� or� need� to� be� custom� ordered.� Tolerances�
�of� 1%� are� recommended� for� accuracy.� Note� that� for� a� typical�
�48V� system� (with� a� 43V� to� 72V� range),� the� 43V� or� 72V� is�
�being� divided� down� to� 1.255V,� a� significant� scaling� factor.�
�For� UV,� the� ratio� is� roughly� 35� times;� every� 3mV� change� on�
�the� UV� pin� represents� roughly� 0.1V� change� of� power� supply�
�voltage.� Conversely,� an� error� of� 3mV� (due� to� the� resistors,�
�for� example)� results� in� an� error� of� 0.1V� for� the� supply� trip�
�point.� The� OV� ratio� is� around� 60.� So� the� accuracy� of� the�
�resistors� comes� into� play.�
�The� hysteresis� of� the� comparators� is� also� multiplied� by� the�
�scale� factor� of� 35� for� the� UV� pin� (35� *� 135mV� =� 4.7V� of�
�hysteresis� at� the� power� supply)� and� 60� for� the� OV� pin�
�(60� *� 25mV� =� 1.5V� of� hysteresis� at� the� power� supply).�
�With� the� three� resistors,� the� UV� equation� is� based� on� the�
�simple� resistor� divider:�
�1.255� =� V� UV� [(R5� +� R6)/(R4� +� R5� +� R6)]� or�
�V� UV� =� 1.255� [(R4� +� R5� +� R6)/(R5� +� R6)]�
�Similarly,� for� OV:�
�1.255� =� V� OV� [(R6)/(R4� +� R5� +� R6)]� or�
�V� OV� =� 1.255� [(R4� +� R5� +� R6)/(R6)]�
�Note� that� there� are� two� equations,� but� 3� unknowns.� Because�
�of� the� scale� factor,� R4� has� to� be� much� bigger� than� the� other�
�two;� chose� its� value� first,� to� set� the� current� (for� example,�
�50V/500k� ?� draws� 100μA),� and� then� the� other� two� will� be� in�
�the� 10k� ?� range.� Solve� the� two� equations� for� two� unknowns.�
�Note� that� some� iteration� may� be� necessary� to� select� values�
�that� meet� the� requirement,� and� are� also� readily� available�
�standard� values.�
�The� three� resistor� divider� (R4,� R5,� R6)� is� the� recommended�
�approach� for� most� applications,� but� if� acceptable� values�
�can’t� be� found,� then� consider� 2� separate� resistor� dividers�
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