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�NCP1028�
�5.0� V/3.0� A� Universal� Mains� Power� Supply�
�Due� to� its� low� R� DS(on)� ,� the� NCP1028� can� be� used� in�
�universal� mains� SMPS� up� to� 15� W� of� continuous� power,�
�provided� that� the� chip� power� dissipation� is� well� under�
�control.� That� is� to� say� that� average� power� calculations� and�
�measurements� have� been� carried� and� correlated.� The�
�design� of� an� SMPS� around� a� monolithic� device� does� not�
�differ� from� that� of� a� standard� circuit� using� a� controller� and�
�a� MOSFET.� However,� one� needs� to� be� aware� of� certain�
�characteristics� specific� of� monolithic� devices.� Let� us�
�follow� the� steps:�
�V� in� min� =� 120� Vdc�
�V� in� max� =� 375� Vdc�
�V� out� =� 5.0� V�
�V� out� =� 15� W�
�Operating� mode� is� CCM�
�h� =� 0.8�
�1.� The� lateral� MOSFET� body-diode� shall� never� be�
�forward� biased,� either� during� startup� (because� of� a�
�large� leakage� inductance)� or� in� normal� operation�
�as� shown� by� Figure� 42.� This� condition� sets� the�
�maximum� voltage� that� can� be� reflected� during� t� off� .�
�350�
�250�
�150�
�50.0�
�>� 0� !!�
�-�
�50.0�
�1.004M�
�1.011M�
�1.018M�
�1.025M�
�1.032M�
�+� 110� +� 18.3� or�
�Vin�
�5� )� 1�
�Vout� )� Vf�
�d� max� +�
�+�
�+� 0.49�
�NVout� )� Vin,� min�
�(eq.� 16)�
�1� )� NV�
�Figure� 42.� The� reflected� voltage� shall� always� be� greater�
�than� the� minimum� input� voltage� to� avoid� the� forward�
�biasing� of� the� MOSFET� body-diode.�
�As� a� result,� the� Flyback� voltage� which� is� reflected� on� the�
�drain� at� the� switch� opening� cannot� be� larger� than� the� input�
�voltage.� When� selecting� components,� you� thus� must� adopt�
�a� turn� ratio� which� adheres� to� the� following� equation:�
�N(Vout� )� Vf)� t� Vin,� min� t� Vin� min� (eq.� 14)� .� In� our� case,�
�since� we� operate� from� a� 120� V� DC� rail� while� delivering�
�5.0� V,� we� can� select� a� reflected� voltage� of� 110� V�
�DC� maximum:� 120-110� >� 0.� Therefore,� the� turn� ratio�
�Np:Ns� must� be� smaller� than�
�Np� :� Ns� t� 19� .� We� will� see� later� on� how� it� affects� the�
�calculation.�
�2.� Lateral� MOSFETs� have� a� poorly� doped�
�body-diode� which� naturally� limits� their� ability� to�
�sustain� the� avalanche.� A� traditional� RCD�
�clamping� network� shall� thus� be� installed� to�
�protect� the� MOSFET.� In� some� low� power�
�Figure� 43.� Primary� Inductance� Current�
�Evolution� in� CCM�
�turn� ratio,� V� out� the� output� voltage,� V� f� the�
�secondary� diode� forward� drop� and� finally,� I� peak�
�the� maximum� peak� current.� Worse� case� occurs�
�when� the� SMPS� is� very� close� to� regulation,� e.g.�
�the� V� out� target� is� almost� reached� and� I� peak� is� still�
�pushed� to� the� maximum.� For� this� design,� we� have�
�selected� our� maximum� voltage� around� 650� V� (at�
�V� in� =� 375� Vdc).� This� voltage� is� given� by� the� RCD�
�clamp� installed� from� the� drain� to� the� bulk�
�voltage.� We� will� see� how� to� calculate� it� later� on.�
�3.� Calculate� the� maximum� operating� duty-cycle� for�
�this� flyback� converter� operated� in� CCM:�
�NVout� 1�
�Vin,min�
�out�
�4.� To� obtain� the� primary� inductance,� we� have� the�
�choice� between� two� equations:�
�)� Ipeak�
�(eq.� 15)� ,� where� L� f� is� the� leakage�
�L� +� ,� where� K� +�
�and�
�applications,� a� simple� capacitor� can� also� be� used�
�since� Vdrain� max� +� Vin� )� N� (Vout� )� Vf)�
�Lf�
�Ctot�
�inductance,� C� tot� the� total� capacitance� at� the� drain�
�node� (which� is� increased� by� the� capacitor� you�
�will� wire� between� drain� and� source),� N� the� Np:Ns�
�?�
�(Vind)2� D� IL�
�(eq.� 17)�
�fSWKPin� I1�
�defines� the� amount� of� ripple� we� want� in� CCM�
�(see� Figure� 43).�
�Small� K:� deep� CCM,� implying� a� large� primary�
�inductance,� a� low� bandwidth� and� a� large� leakage�
�inductance.�
�http://onsemi.com�
�24�
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