AND8293/D Implementing an LCD TV Power Supply with the NCP1396A, NCP1605, and NCP1027 http://onsemi.com Prepared by Roman Stuler Introduction Timer Based Fault Protection This document provides a detailed description of the implementation of an LCD TV power supply. The LDC TV supply unit exhibits high efficiency, low EMI noise and a low profile construction. The board contains DCM/CCM PFC front stage, 210 W LLC power stage and 12.5 W standby flyback converter. The design requirements for our LCD TV power unit are as follows: The converter stops operation after a programmed delay when the protection is activated. This protection can be implemented as a cumulative or integrating characteristic. Thus, under transient load conditions the converter output will not be turned off, unless the extreme load condition exceeds the timeout. Min Max Unit Input Voltage Requirement 90 265 Vac Output Voltage 1 - 12 Vdc Output Current 1 0 3 A Output Voltage 2 - 24 Vdc Output Current 2 0 6 A Output Voltage 3 - 30 Vdc Output Current 3 0 1 A Output Voltage Standby Output - 5 Vdc Output Current Standby Output 0 2.5 A Total Output Power 0 222.5 W Total No Load Consumption for 0.5W Load on the Standby Output - 1 W NOTE: Common Collector Optocoupler Connection The open collector output allows multiple inputs on the feedback pin i.e. over current sensing circuit, over temperature sensor, etc. The additional input can pull up the feedback voltage level and take over the voltage feedback loop. 600 V High Voltage Floating Driver The high side driver features a traditional bootstrap circuitry, requiring an external high-voltage diode for the capacitor refueling path. The device incorporates an upper UVLO circuitry that guarantees enough Vgs is available for the upper side MOSFET. Adjustable Dead-Time (DT) Due to a single resistor wired between DT pin and ground, the user has the option to include needed dead- time, helping to fight cross- conduction between the upper and the lower transistor. Only 24 V output is regulated in this version of the board. Additional output(s) regulation can be assured by adding feedback resistors to desired output (or outputs for percentage weight). Adjustable Minimum and Maximum Frequency Excursion Using a single external resistor, the designer can program its lowest frequency point, obtained in lack of feedback voltage (during the startup sequence or in short- circuit conditions). Internally trimmed capacitors offer a $3% precision on the selection of the minimum switching frequency. The adjustable maximum frequency is less precise ($15%). Please refer to the NCP1396A/B data sheet for detailed description of all mentioned and additional features. The NCP1396A resonant mode controller has been selected for this application because the soft- start absence on the fast fault input offers an easy implementation of the skip cycle mode. This helps to assure regulation of the resonant converter under no load conditions. The NCP1396A offers many other features that are advantageous for our application. Brown-Out (BO) Protection Input The input voltage of the resonant converter, when divided down, is permanently monitored by the Brownout pin. If the voltage on the bulk capacitor falls outside of the desired operating range, the controller drive output will be shut off. This feature is necessary for an LLC topology that uses PFC stage without PFC OK control output. In our case the BO input is used as an enabling input and is fully controlled by the front stage controller output (PFC OK). © Semiconductor Components Industries, LLC, 2007 June, 2007 - Rev. 1 Detailed Demo Board Connection Description A schematic of the proposed LCD TV power supply is shown in Figure 1. As already mentioned, the supply contains three blocks: a PFC front stage, an LLC converter and an auxiliary flyback converter that powers a TV set during standby and provides bias power for PFC and LLC control circuits during normal operation. 1 Publication Order Number: AND8293/D AND8293/D Figure 1. Schematic of the NCP1396A LCD TV Application http://onsemi.com 2 AND8293/D PFC Front Stage voltage range is restricted by the Brown Out sensing network R64, R68, R70, R77 and C48. The NCP1027 switcher features adjustable ramp compensation capability - resistor R78. Feedback loop is accomplished in the standard way: the output voltage level is regulated by the IC6 to the value which is defined by resistors R74 and R80. Bias current for optcoupler OK3 and regulator is provided from the standby supply output using resistors R72 and R73. Resistors R75 and R79 are used to stabilize the maximum output power level with bulk voltage evaluation (CS comparator delay compensation). A standard RCD voltage clamp (R66, R67, C41, D21) is installed on the switcher drain to limit its voltage to safe level. There is an optional layout on the board so the TVS (D19) can be used instead of the RCD clamp. This solution further decreases standby power consumption, however, price is slightly higher. Voltage from auxiliary winding, which is used to power the switcher is also used to feed up the PFC front stage and the main LLC converter control circuits. This voltage is limited by a simple zener regulator (D22, Q7, R76 and C46) and can be inhibited by the OK2 action. Standby mode can be activated either by positive or negative logic signals (Q5 or Q6 assembled). Please refer to the application note AND8241/D for a detailed explanation on how to design a Standby flyback converter using the NCP1027 switcher. The NCP1605 (IC1) PFC controller is used for PFC front stage control. This front stage works either in fixed frequency discontinues mode or critical conduction mode depends on the line and load conditions. Capacitors C42, C30, CY1, CY2 with common mode choke L9, inductors L6, L7 and varistor R28 form the EMI filter, which suppresses noise conducted to the mains. A bridge rectifier B1 is used to rectify the input AC line voltage. Capacitor C5 filters the high frequency ripple current, which is generated by the PFC operation. In this application a classical PFC boost topology is used. The PFC power stage is formed by inductor L2, MOSFET switch Q2, diode D4, bulk capacitors C6, C7 and inrush current bypassing diode D2. The current in the PFC stage is monitored by current sense network R13, R14 and R15. Right input voltage operating range is adjusted by the Brown Out sensing network R2, R5, R10, R16, R36 and C21. Output voltage of the PFC stage is regulated to a nominal 395 Vdc via the feedback network R3, R6, R11, R22, R29 and R30. Sensing network described above is also used to monitor an overvoltage condition on the PFC output using the NCP1605 OVP pin. PFC regulation loop bandwidth is limited by the capacitor C22. The sensitivity of the zero current detection circuitry is given by the resistor R39 value. Capacitor C19 and resistor R40 are used to control the maximum Q2 switch on-time. Capacitor C24 dictates the DCM operating frequency. Skip mode of the PFC front stage is initiated by the NCP1605 controller when the voltage on the STBY pin is lower than 0.3 V. Since the LLC stage voltage feedback and also bulk capacitor voltage have opposing reaction function (increasing when output load decreases), the divided (R35, R43 and C25) LLC stage primary current information has been used to trigger the PFC skip mode during light load conditions. The controller receives the VCC voltage from standby stage when standard operation mode is enabled by the TV set application. Please refer to the application note AND8281/D for a detailed explanation on how to design a PFC front stage using the NCP1605 controller. LLC Power Stage As previously mentioned, the NCP1396A (IC3) resonant mode controller is used to control the main SMPS unit. The power stage of the LLC converter is formed by bulk capacitors C6, C7, MOSFETs Q1, Q3, transformer TR1 and resonant capacitor C11. MOSFETs are driven directly by the controller. Resistors R19 and R20 damp the gate charging circuit to suppress overshoots on the gates and regulate EMI noise. Bootstrap diode D14 is charging the bootstrap capacitor C28 via resistor R42. The bootstrap capacitor powers a floating driver when high side MOSFET is turned on. Safety resistors R4 and R12 are used to protect MOSFETs (during the experiments on the bench, for instance, when IC3 is removed). Center-tapped windings on 12 V and 24 V outputs increase the converter efficiency. A bridge rectifier is used for 30 V output. Different shottky diode types (D3 with D5, D6 through D10 and D11) are used for secondary rectification according to output voltage, power losses and also short circuit capability (not to damage diode during hard short on the output). The low ESR, high temperature electrolytic capacitors C1 through C4, C8 through C10, C12 through C16, together with inductors L1, L4, and L5 serve as filters for corresponding outputs. The secondary voltage regulator IC2 regulates the output voltage to 24 V, which is value adjusted by resistor divider composed by R24, R48 and R49. If needed, there can be optionally used feedback from other secondary output(s) (R26 and R27 are included in the board layout). On the primary side, the optocoupler works in the connection with a common collector which also allows an easy implementation of the current regulation loop. Maximum Standby Supply An ON Semiconductor NCP1027 monolithic switcher (IC5) is used for auxiliary (or standby) power stage provide a cost effective solution, needed output power and low standby consumption, since this switcher offers skip mode capability under light load conditions. The nominal output power of this converter is 12.5 W. The unit is connected directly to the bulk capacitors so during standby conditions it operates from rectified mains. During normal operating conditions the switcher is energized by higher voltage (PFC front stage is working). After the start (that is assured by internal current supply) the switcher is powered from the auxiliary winding. Diode D23 is used for rectification and capacitor C47 to filter auxiliary voltage. Resistor R71 limits the ICC current so the auto-recovery OVP is not activated for the correct VCC voltage. The appropriate operating bulk http://onsemi.com 3 AND8293/D converters, offers extra high leakage inductance value thanks to a special windings arrangement (see demo board photo in Figure 24). The leakage inductance serves as a resonant inductance, which results in a cost effective solution since no additional inductor is needed to form a resonant tank. Specified parameters of the mentioned transformer are as follows: current through the optocoupler transistor is adjusted by a resistor R33. To speed up the regulation response, resistor R47 is connected to the feedback pin. Capacitor C34 defines the soft start length. Note that the current regulation loop is used in this power stage so it takes control during the startup and affects the soft start action. Resistors R53, R55 and R57 define maximum operating frequency, minimum operating frequency and dead time. The operation/fault time period during the overload is dictated by C35 and R54 values. The LLC power stage operation is conditioned to the correct PFC front stage operation indicated by the PFC OK signal. This signal, divided down by resistors R32 and R56, enables the NCP1396A controller when the bulk voltage is in the right range (PFC stage reached regulation). Resistor divider R51 and R58 with bypass capacitor C37 are used to prepare skip mode during light or no load conditions on the power stage output. This skip mode limits the maximum needed operating frequency of the converter and improves no load efficiency of the LLC stage. As already mentioned, the current feedback loop is used in this design. It limits the primary current of the power stage during overload and helps to implement hick-up mode. Primary current is sensed using charge pump R17, C18, D12, D13. Output of this charge pump is divided and filtered by R31, R18 and C17. Maximum value of this voltage (and thus also the primary current) is regulated to 1.24 V by IC4 regulator. The compensation of current regulation loop is accomplished by C31 capacitor. Zener diode D15 is used to lower maximum voltage on IC4. Since we need to bring up the NCP1396 feedback pin to increase the operating frequency during overload, transistor Q4 with resistors R38 and R44 are used to perform inversion. Output voltage on the Q4 collector is limited by zener diode D18 to 7.5 V maximally. This voltage divided down by resistors R52 and R59 triggers the slow fault input in case of an overload and also drives the NCP1396A feedback pin via diode D17. This diode assures that the slow fault input is not triggered during light load conditions and in skip mode when the IC3 feedback pin voltage is pushed up by the voltage feedback loop. Controller IC3 receives the VCC voltage from standby stage during normal operation mode. Auxiliary winding of the resonant transformer W7 (when half wave rectified by D1) helps to power the control circuits when load on the standby supply output is too low and there is a lack of voltage on the standby auxiliary winding due to pure flyback transformer coupling. Please note that all outputs of the converter (including standby stage) are referenced to one secondary ground (S_GND). Leakage (Resonant) Inductanc Magnetizing Inductance Primary Turns Count 24 V Output Turns Count 12 V Output Turns Count 30 V Output Turns Count Auxiliary Winding Turns Count Lm/Ls Ratio Ls = 115 mH Lm = 450 mH 38 4 2 5 3 450/115 = 3.9 Low value of the Lm/Ls ratio together with high turns ratio of the transformer will result in the high gain values. Note that the manufacturer specifies the LS inductance in a standard way - all secondary windings are shorted during the Ls measurements. This approach is OK for a transformer that has one secondary winding, but in our case we have three different secondary windings and two of them are center taped so only one of the corresponding winding participates on the resonance during one half of the switching period. As a result, the real leakage inductance that participates on the resonance is higher. Due to this fact, the simulation results of gain characteristics that are accomplished based on the transformer datasheet values, are not accurate enough to determine operating frequency range of the proposed converter. The most accurate method how to obtain gain characteristics of the LLC converter that uses integrated transformer solution with multiple outputs, is to use a gain-phase analyzer. To do so it is necessary to load measured transformer outputs by equivalent AC resistances before measurements (first fundamental approximation see [5] and [6]). For the center taped windings connect the AC resistance only to one of the windings of the pair - this will happen in reality - only one diode conducts the current during one half of the switching period. The AC resistance for corresponding output can be calculated using Equation 1. R ac + 8 V out ) V f p2 (eq. 1) I out Where: Vout is the DC output voltage for given output Vf is the rectifier forward voltage Iout is the DC output current from given output The output current has to be selected based on what type of gain characteristics one wants to obtain - full load, 10% load etc. Connection of the transformer during the gain characteristics measurements can be seen in Figure 2. LLC Transformer and Resonant Tank A transformer from the standard production of the Pulse engineering company has been used for this design. This transformer, which is specially designed for LLC http://onsemi.com 4 AND8293/D • The minimum needed operating frequency to assure low line regulation is 79 kHz • The maximum needed operating frequency to assure high line regulation is 106 kHz • The converter will operate in the calculated series resonant frequency for Vbulk = 360 VDC As demonstrated, the converter will operate above the calculated theoretical series resonant frequency for nominal bulk voltage and full load. The ZCS capability is thus not achieved on the secondary diodes. Also the needed operating frequency range of this converter is very narrow, which is beneficial for LCD TV application - EMI radiation and filtering. Gain characteristic of this converter for Iload = 0.10 * Imax and same parameters as above is in Figure 4. 0.21 0.19 Figure 2. Transformer Connection During Gain Characteristics Measurements GAIN (-) 0.17 The resonant tank quality factor of Q = 4.3 (that corresponds to resonant capacitor Cr = 33 nF) has been selected for this design in order to narrow operating frequency range of the converter. The measured full load gain characteristic for the selected resonant tank components and 24 V output can be observed in Figure 3. The gains that are needed to assure line regulation can be calculated using Equations 2 through 4: G nom + G max + V inmax 2ǒV out ) V fǓ V innom 2ǒV out ) V fǓ V inmax + + 2(24 ) 0.6) 425 2(24 ) 0.6) 395 + 0.116 (eq. 2) + 0.125 (eq. 3) + Gmax 0.125 0.11 Gmin 0.07 0.05 2.0E+04 6.0E+04 1.0E+05 1.4E+05 1.8E+05 FREQUENCY (Hz) Figure 3. FLLC Converter Gain Characteristic for Full Load and Q = 4.3 (Cr = 33 nF) 2 1.8 1.6 + 2(24 ) 0.6) 350 1.4 + 0.141 (eq. 4) Theoretical series resonant frequency can also be calculated based on the Equation 5: f r1 + 0.13 Operating Point for Vbulk = 395 V and Full Load 0.09 GAIN (-) G min + 2ǒV out ) V fǓ 0.15 1.2 1 0.8 1 0.6 2 @ p @ ǸL r @ C r 0.4 (eq. 5) 1 2 @ 3.14 @ Ǹ115 @ 10 - 6 @ 33 @ 10 - 9 0.2 + 81.7kHz 0.125 0 2.E+04 Now, when looking back to the gain characteristic in Figure 3, the operating conditions of the full loaded LLC power stage can be read: • The nominal operating frequency of such converter is 94.6 kHz (for nominal bulk voltage) 6.E+04 Operating Point for Vbulk = 395 V and Full Load 100kHz 1.E+05 1.E+05 2.E+05 FREQUENCY (Hz) Figure 4. LLC Converter gain Characteristic for 10 % Load Conditions http://onsemi.com 5 AND8293/D This characteristic shows that the operating frequency has to be increased above 100 kHz to maintain regulation under light load conditions. Skip mode for the LLC stage can thus be easily implemented when maximum frequency is limited by Fmax adjust resistor value. Please refer to the application notes AND8255/D and AND8257/D for further information about the LLC converter resonant tank components design. Standby (PFC and LLC disabled) consumption characteristic with line voltage for 0.5 W load on the standby output is in Figure 7. The consumption is below 1 W for any input voltage so today's energy agency's needs are easily met thanks to this design. 950 900 Results Summarization PIN (mW) Operating frequency of real LLC stage is 96.1 kHz for full load and Vbulk = 395 VDC, which is very close to the theoretical expectations. Output current level during which the skip mode takes place (LLC stage) has been set approximately to 8 W by R50, R57 divider. The PFC stage enters skip mode for output power lower than 25 W and leaves it for Pout > 30 W. Measured efficiency for different input voltages and load conditions can be seen in Figures 5 and 6. 850 800 750 700 85 0.92 EFFICIENCY (-) EM 230 0.88 EM 110 0.86 0.84 0.82 0.8 40 60 80 100 120 140 160 180 200 220 TOTAL OUTPUT POWER (W) Figure 5. Total Efficiency versus Output Power and Line 0.915 FULL LOAD EFFICIENCY (-) 0.91 0.905 0.9 0.895 0.89 0.885 0.88 0.875 0.87 0.865 0.86 90 110 130 125 145 165 185 205 VIN (VAC) 225 245 265 Figure 7. Standby Consumption versus Line Voltage - 0.5 W Load on STB Output 0.9 0.78 20 105 150 170 190 210 INPUT VOLTAGE (VAC) 230 250 Figure 6. Total Full Load Efficiency versus Input Voltage http://onsemi.com 6 AND8293/D Figure 8. LLC Converter Waveforms During Skip Mode (1 - Bridge Voltage, 2 - Output Ripple on 12 V Output, 3 - Feedback Pin of the NCP1396) Figure 9. Output Ripple on Each LLC Stage Output for Full Load Conditions (1 - 24 V Output, 2 - 30 V Output, 3 - 12 V Output) Figure 10. LLC Stage Load Regulation for 230 V Input Voltage (2 - Output Voltage on the 24 V Output, 4 - Output Current from the 24 V Output) Figure 11. LLC Stage Operating Under Short Circuit (1 - Ctimer Voltage, 2 - Feedback Voltage, 4 - Primary Current) Figure 12. LLC Stage Full Load Operation (1 - Bridge Voltage, 4 - Primary Current) Figure 13. Detail of the ZVS Condition on the Bridge - Rising Edge (1 - Bridge Voltage, 4 - Primary Current) http://onsemi.com 7 AND8293/D Figure 14. Detail of the ZVS Condition on the Bridge - Falling Edge (1 - Bridge Voltage, 4 - Primary Current) Figure 15. Standby Power Supply Waveforms Full Loaded (1 - NCP1027 Drain Voltage, 4 - Drain Current) Figure 16. Standby Power Supply Waveforms No Load Conditions (1 - NCP1027 Drain Voltage) Figure 17. PFC Stage Skip Mode (1 - Q2 Drain Voltage, 2 - Bulk Voltage) Layout Consideration 6. Application note AND8257/D 7. Application note AND8281/D 8. Bo Yang - Topology Investigation for Front End DC-DC Power Conversion for Distributed Power System 9. M. B. Borage, S. R. Tiwari and S. Kotaiah Design Optimization for an LCL - Type Series Resonant Converter 10. Pulse Engineering - Transformer specification, No: 2652.0017A 11. Pulse Engineering - Transformer specification, No: 2362.0031B 12. Pulse Engineering - PFC inductor specification, No: 2702.0012A Please contact Pulse Engineering Company regarding literature 10 - 12: Pulse European Headquarters Einsteinstrasse 1 71083 Herrenberg Germany TEL: 49 7032 7806 0 FAX: 49 7032 7806 12 Leakage inductance on the primary side is not very critical for the LLC converter compared to other topologies, because it will only slightly modify the resonant frequency. However it is well to keep the areas of each power loop as small as possible due to radiated EMI noise. A two- sided PCB with one side ground plane helps (see Figures 21 and 23). Thanks I would like to thank the PULSE engineering company for provided samples and support for magnetic components used in this board. I would also like to thank the COILCRAFT company for providing samples of the filtering inductors. CAUTION This demo board is intended for demonstration and evaluation purposes only and not for the end customer. Literature 1. NCP1396A/B data sheet 2. NCP1605 data sheet 3. NCP1027 data sheet 4. Application note AND8241/D 5. Application note AND8255/D http://onsemi.com 8 AND8293/D EN50081-1 (Domestic) Conducted Emissions EN50081-1 (Domestic) Conducted Emissions 90 80 80 70 70 60 60 LEVEL (dBmV) LEVEL (dBmV) 90 50 40 30 50 40 30 20 20 10 10 0 0 100k 500k 1 5 10 30 100k 500k 1 5 10 FREQUENCY (mHz) FREQUENCY (mHz) Figure 18. Conducted EMI Signature of the Board for Full Load and 230 VAC Input Figure 19. Conducted EMI Signature of the Board for Full Load and 110 VAC Input http://onsemi.com 9 30 AND8293/D Figure 20. Component Placement on the Top Side (Top View) http://onsemi.com 10 AND8293/D Figure 21. Top Side (Top View) http://onsemi.com 11 AND8293/D Figure 22. Component Placement on the Bottom Side (Bottom View) http://onsemi.com 12 AND8293/D Figure 23. Bottom Side (Bottom View) http://onsemi.com 13 AND8293/D Figure 24. Photo of the Designed Prototype (Real Dimensions are 200 x 130 mm) http://onsemi.com 14 AND8293/D BILL OF MATERIAL Designator Qty Description Value Toleranc e Footprint Manufacturer Manufacturer Part Number B1 1 Bridge Rectifier KBU8M KBU Fairchild KBU8M C1, C2, C3, C8, C9, C12, C13, C14, C15, C43, C44 11 Electrolytic Capacitor 470mF/35V 20% CPOL-EUE5-10.5 Rubycon 35ZL470M10X20 C10 1 Electrolytic Capacitor 220mF/63V 10% CPOL-EUE5-10.5 Rubycon 63 YXA220M 10x16 C11 1 MKP Capacitor 33nF/630Vdc 20% C-EU150-084X183 Arcotronics R73-0.033 mF 15 630V C16 1 Electrolytic Capacitor 220mF/35V 20% CPOL-EUE5-10.5 Rubycon 35 RX30220M 10x12.5 C17, C48 2 Ceramic Capacitor SMD 10n 10% C-EUC1206 Epcos B37872A5103K060 C18 1 Ceramic Capacitor 220p 10% C-EU050-045X075 Panasonic ECKA3A221KBP C19 1 Ceramic Capacitor SMD 8n2 10% C-EUC1206 Epcos B37872A5822K060 C20, C23, C32, C33, C36, C52 6 C21 1 Ceramic Capacitor SMD 150n 10% C-EUC1206 Epcos B37872A5154K060 C22 1 Ceramic Capacitor SMD 220n 10% C-EUC1206 Epcos B37872A5224K060 C24 1 Ceramic Capacitor SMD 390p 5% C-EUC1206 Epcos B37871K5391J060 C25 1 Ceramic Capacitor SMD 1n2 10% C-EUC1206 Epcos B37872A5122K060 C26, C28, C38, C40, C51 5 Ceramic Capacitor SMD 100n 10% C-EUC1206 Epcos B37872A5104K060 C27 1 Ceramic Capacitor SMD 1n 10% C-EUC1206 Epcos B37872A5102K060 C29 1 Ceramic Capacitor SMD 22n 10% C-EUC1206 Epcos B37872A5223K060 C31 1 Ceramic Capacitor SMD 68n 10% C-EUC1206 Epcos B37872A5683K060 C34 1 Ceramic Capacitor SMD 1mF 10% C-EUC1206 Epcos B37872K0105K062 C35 1 Electrolytic Capacitor 4m7/35V 20% CPOL-EUE2-5 Rubycon 35 MH54.7M 4x5 C37 1 Ceramic Capacitor SMD 2n2 10% C EUC1206 Epcos B37872A5222K060 Rubycon 25 NXA220M 10x12.5 NU C-EUC1206 C39 1 C4, C45 2 Electrolytic Capacitor 220mF/25V 20% CPOL-EUE5-10.5 C41 1 MKP Capacitor 10nF/630Vdc 20% C-EU075-032X103 Epcos B32560J8103M000 C46 1 Electrolytic Capacitor 1u 20% CPOL-EUE2-5 Rubycon 50 MH51M 4x5 C47 1 Electrolytic Capacitor 100uF/35V 20% CPOL-EUE5.5-8 Rubycon 50 PK100M 8x11.5 C49 1 Electrolytic Capacitor 10mF/35V 20% CPOL-EUE2.5-6 Rubycon 50 MH710M 6.3x7 C5, C30, C42 3 MKP Capacitor 1mF/275Vac 20% C-EU225-108X268 Arcotronics R46KM410000N1M C50 1 Ceramic Capacitor SMD 100p 20% C-EUC1206 Epcos B37871K5101J060 NOTE: NU C-EU150-064X183 Please see the NCP1396A/B product folder on www.onsemi.com for PCB Gerber files and other collateral information regarding this demo board. http://onsemi.com 15 AND8293/D BILL OF MATERIAL Designator Qty Description Value Toleranc e Footprint Manufacturer Manufacturer Part Number C6 1 Electrolytic Capacitor 100mF/450V 20% EC18L40'22L35' Rubycon 450 VXG100M 22x30 C7 1 Electrolytic Capacitor 100mF/450V 20% EC18L40'22L35_90' Rubycon 450 VXG100M 22x30 CY1, CY2, CY3 3 Ceramic Capacitor 2n2/Y1 20% CYYC10B4 Murata DE1E3KX222MA5B D1, D8, D12, D13, D17 5 Diode MMSD4148 SOD-123 ON Semiconductor MMSD4148T1G D11 1 Dual Diode MBRF20100CT TO-220 ON Semiconductor MBRF20100CTG D14, D21, D23 3 Diode MURA160SMD SMA ON Semiconductor MURA160T3G D15 1 Zener Diode 3V3 SOD-123 ON Semiconductor MMSZ3V3T1G D16 1 D18 1 ON Semiconductor MMSZ7V5T1G D19 1 D2 1 D20 5% NU Zener Diode 7V5 SOD-123 5% SOD-123 NU SMA Diode 1N5408 Axial Lead 9.50x5.30mm ON Semiconductor 1N5408G 1 Diode MBRS340T3 SMC ON Semiconductor MBRS320T3G D22 1 Zener Diode 18V SOD-123 ON Semiconductor MMSZ18T1G D3, D5, D6, D7, D9, D10 6 Diode MBRS4201T3G 5% SMC ON Semiconductor MBRS4201T3G D4 1 Diode MSR860 TO-220 ON Semiconductor MSR860G F1 1 FUSEHOLDER , 20X5MM SH22, 5A SH22, 5A Multicomp MCHTC-15M 1 COVER, PCB FUSEHOLDER Multicomp MCHTC-150M 1 FUSE, MEDIUM DELAY 4A 4A BUSSMANN TDC 210-4A HEATSING_ 1 1 Heatsing SK 454 150 SA SK454/150_GND Fischer Elektronik SK 454 150 SA HEATSING_ 2 1 Heatsing SK 454 100 SA SK454/100_GND Fischer Elektronik SK 454 100 SA IC1 1 PFC Controller NCP1605 SOIC 16 ON Semiconductor NCP1605DR2G IC2, IC6 2 Programmable Precision Reference TL431SO8 SOIC-8 ON Semiconductor NCV431AIDR2G IC3 1 Resonant Controller NCP1396A SOIC 16 ON Semiconductor NCP1396ADR2G IC4 1 Programmable Precision Reference TLV431A SOT-23 ON Semiconductor TLV431ASN1T1G IC5 1 HV Switcher for Medium Power Offline SMPS NCP1027 PDIP (8 Minus Pin 6) ON Semiconductor NCP1027P065G J1, J3 2 Connector 22-23-2071 MOLEX-7PIN Molex 22-23-2071 J2 1 Connector 22-23-2101 MOLEX-10PIN Molex 22-23-2101 J4 1 Connector 22-23-2051 MOLEX-5PIN Molex 22-23-2051 J5 1 Connector LP7.5/2/903.2 OR Weidmueller Weidmueller LP7.5/2/903.2 OR L1, L4, L5, L10 4 Inductor 2m2 20% RFB0807 Coilcraft RFB0807-2R2L L2 1 Inductor 2702.0012A (260mH) 15% Pulse_2702 Pulse 2702.0012A L3 1 L6, L7 2 20% DO5040H_100 Coilcraft DO5040H-104MLB NOTE: NU Inductor 100m 2722.0005A Please see the NCP1396A/B product folder on www.onsemi.com for PCB Gerber files and other collateral information regarding this demo board. http://onsemi.com 16 AND8293/D BILL OF MATERIAL Designator Qty L8 1 L9 Toleranc e Footprint Value 1 EMI Filter 7mH TLBI Pulse 6001.0069 OK1, OK2, OK3 3 Opto-Coupler PC817 PC817SMD Avago Technologies HCPL-817-300E Q1, Q3 2 MOSFET Transistor STP12NM50FP TO-220 STMicroelectronics STP12NM50FP Q2 1 MOSFET Transistor STP20NM60FP TO-220 STMicroelectronics STP12NM50FP Q4 1 PNP General Purpose Transistor BC856-16L T1 SOT-23 ON Semiconductor BC856-16L T1G Q5, Q7 2 NPN General Purpose Transistor BC817-16L T1 SOT-23 ON Semiconductor BC817-16L T1G Q6 1 NU SOT-23 R1, R8, R19, R20 4 Resistor SMD 10R 1% R-EU_R1206 Vishay RCA120610R0FKEA R13 1 Resistor Trough Hole 0.1R 1% R-EU_0617/22 Vishay PAC300001007FAC000 NU Manufacturer Manufacturer Part Number Description TLBI 15% R14 1 Resistor SMD 7k5 1% R-EU_R1206 Vishay RCA12067K50FKEA R15, R51 2 Resistor SMD 8k2 1% R-EU_M1206 Vishay RCA12068K20FKEA R17 1 Resistor SMD 47k 1% R-EU_M1206 Vishay RCA120647K0FKEA R18 1 Resistor SMD 1k6 1% R-EU_M1206 Vishay RCA12061K60FKEA R2, R5, R10, R16 4 Resistor SMD 1M8 1% R-EU_M1206 Vishay RCA12061M80FKEA R21, R25, R26, R27, R37, R46, R50 7 Resistor SMD NU 1% R-EU_M1206 Vishay R22 1 Resistor SMD 1k1 1% R-EU_M1206 Vishay RCA12061K10FKEA R23, R33, R34, R38, R41, R73 6 Resistor SMD 1k 1% R-EU_M1206 Vishay RCA12061K00FKEA R24, R77 2 Resistor SMD 18k 1% R28 1 Varistor VDRH10S275TSE R-EU_M1206 Vishay RCA120618K0FKEA VARISTOR10K300 Vishay 2381 584 T271S R29 1 Resistor SMD 33k 1% R-EU_M1206 Vishay RCA120633K0FKEA R3, R6, R11 3 Resistor SMD 1M3 1% R-EU_R1206 Vishay RCA12061M30FKEA R30 1 Resistor SMD 91k 1% R-EU_M1206 Vishay RCA120691K0FKEA R31, R48 2 Resistor SMD 3k3 1% R-EU_M1206 Vishay RCA12063K30FKEA R32, R39, R55 3 Resistor SMD 15k 1% R-EU_R1206 Vishay RCA12061K50FKEA R36 1 Resistor SMD 62k 1% R-EU_M1206 Vishay RCA120662K0FKEA R4, R9, R12, R35, R43, R44, R52, R57, R61, R74, R79, R80 12 Resistor SMD 10k 1% R-EU_M1206 Vishay RCA120610K0FKEA R40 1 Resistor SMD 150R 1% R-EU_R1206 Vishay RCA1206150RFKEA R42 1 Resistor SMD 18R 1% R-EU_R1206 Vishay RCA120618R0FKEA R45 1 Resistor SMD 2k7 1% R-EU_M1206 Vishay RCA12062K70FKEA R47 1 Resistor SMD 2k2 1% R-EU_R1206 Vishay RCA12062K20FKEA R49 1 Resistor SMD 5k6 1% R-EU_M1206 Vishay RCA12065K60FKEA R53 1 Resistor SMD 24k 1% R-EU_R1206 Vishay RCA120624K0FKEA NOTE: Please see the NCP1396A/B product folder on www.onsemi.com for PCB Gerber files and other collateral information regarding this demo board. http://onsemi.com 17 AND8293/D BILL OF MATERIAL Designator Qty Description Value Toleranc e Footprint Manufacturer Manufacturer Part Number R54 1 Resistor SMD 150k 1% R-EU_R1206 Vishay RCA1206150KFKEA R56 1 Resistor SMD 6k8 1% R-EU_R1206 Vishay RCA12066K80FKEA R58 1 Resistor SMD 1k5 1% R-EU_R1206 Vishay RCA12061K50FKEA R59 1 Resistor SMD 6k2 1% R-EU_R1206 Vishay RCA12066K20FKEA R60, R62, R63 3 Resistor SMD 820R 1% R-EU_R1206 Vishay RCA1206820RFKEA R64, R68 2 Resistor SMD 1M2 1% R-EU_R1206 Vishay RCA12061M20FKEA R65 1 Resistor SMD 4k7 1% R-EU_R1206 Vishay RCA12064K70FKEA R66 1 Resistor Trough Hole 150k 1% R-EU_0207/10 Vishay MRS25000C1503FCT R67 1 Resistor Trough Hole 47R 1% R-EU_0207/10 Vishay MRS25000C4709FCT R69 1 Option for Thermistor 0R0 R7 1 Resistor SMD 0R0 1% R-EU_M1206 Vishay RCA12060000FKEA R70 1 Resistor SMD 180k 1% R-EU_M1206 Vishay RCA1206180KFKEA R71 1 Resistor SMD 3k9 1% R-EU_M1206 Vishay RCA12063K90FKEA R72 1 Resistor SMD 100R 1% R-EU_M1206 Vishay RCA1206100RFKEA R75 1 Resistor SMD 360k 1% R-EU_M1206 Vishay RCA1206360KFKEA R76 1 Resistor SMD 470k 1% R-EU_R1206 Vishay RCA1206470KFKEA R78 1 Resistor SMD 75k 1% R-EU_M1206 Vishay RCA120675K0FKEA R81 1 Resistor Trough Hole, High Voltage 4M7 5% R-EU_0414/15 Vishay VR37000004704JA100 TR1 1 Resonant Transformer 2652.0017A 15% 2652 Pulse 2652.0017A TR2 1 Standby Transformer 2362.0031B 15% 2362 Pulse 2362.0031B P594 B1 1 Bridge Rectifier KBU8M KBU Fairchild KBU8M C1, C2, C3, C8, C9, C12, C13, C14, C15, C43, C44 11 Electrolytic Capacitor 470mF/35V 20% CPOL-EUE5-10.5 Rubycon 35ZL470M10X20 C10 1 Electrolytic Capacitor 220mF/63V 10% CPOL-EUE5-10.5 Rubycon 63 YXA220M 10x16 C11 1 MKP Capacitor 33nF/630Vdc 20% C-EU150-084X183 Arcotronics R73-0.033uF 15 630V C16 1 Electrolytic Capacitor 220mF/35V 20% CPOL-EUE5-10.5 Rubycon 35 RX30220M 10x12.5 C17, C48 2 Ceramic Capacitor SMD 10n 10% C-EUC1206 Epcos B37872A5103K060 NOTE: Please see the NCP1396A/B product folder on www.onsemi.com for PCB Gerber files and other collateral information regarding this demo board. ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages. “Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals” must be validated for each customer application by customer's technical experts. SCILLC does not convey any license under its patent rights nor the rights of others. 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