capzero family zero 1 loss automatic x capacitor discharge ic www.powerint.com april 2011 ? component selection table product 3 bv dss maximum total x capacitance total series resistance 2 (r1 + r2) cap002dg 825 v 500 nf 1.5 m w cap012dg 1000 v cap003dg 825 v 750 nf 1.02 m w cap013dg 1000 v cap004dg 825 v 1 m f 780 k w cap014dg 1000 v cap005dg 825 v 1.5 m f 480 k w cap015dg 1000 v cap006dg 825 v 2 m f 360 k w cap016dg 1000 v cap007dg 825 v 2.5 m f 300 k w cap017dg 1000 v cap008dg 825 v 3.5 m f 200 k w cap018dg 1000 v cap009dg 825 v 5 m f 150 k w cap019dg 1000 v table 1. component selection table. notes: 1. iec 62301 clause 4.5 rounds standby power use below 5 mw to zero. 2. values are nominal. rc time constant is <1 second with 20% x capacitor and 5% resistance from these nominal values. 3. packages: d: so-8. product highlights ? blocks current through x capacitor discharge resistors when ac voltage is connected ? automatically discharges x capacitors through discharge resistors when ac is disconnected ? simplifes emi flter design C larger x capacitor allows smaller inductive components with no change in consumption ? only two terminals C meets safety standards for use before or after system input fuse ? >4 mm creepage on package and pcb ? self supplied C no external bias required ? high common mode surge immunity C no external ground connection ? high differential surge withstand C 1000 v internal mosfets ecosmart ? C energy effcient ? <5 mw consumption at 230 vac for all x capacitor values applications ? all acdc converters with x capacitors >100 nf ? appliances requiring eup lot 6 compliance ? adapters requiring ultra low no-load consumption ? all converters requiring very low standby power description when ac voltage is applied, capzero blocks current fow in the x capacitor safety discharge resistors, reducing the power loss to less than 5 mw, or essentially zero 1 at 230 vac. when ac voltage is disconnected, capzero automatically discharges the x capacitor by connecting the series discharge resistors. this operation allows total fexibility in the choice of the x capacitor to optimize differential mode emi fltering and reduce inductor costs, with no change in power consumption. designing with capzero is simply a matter of selecting the appropriate capzero device and external resistor values in table 1 for the x capacitor value being used. this design choice will provide a worst case rc time constant, when the ac supply is disconnected, of less than 1 second as required by international safety standards. the simplicity and ruggedness of the two terminal capzero ic makes it an ideal choice in systems designed to meet eup lot 6 requirements. the capzero family has two voltage grades: 825 v and 1000 v. the voltage rating required depends on surge requirement and circuit confguration of the application. see key applications considerations section for details. figure 1. typical application C not a simplifed circuit. pi-5607-041210 d1 r1 ac r2 x capacitor capzero d2 mov and other emi filter components
rev. c 04/11 2 capzero family www.powerint.com figure 2. pin confguration. pin functional description the pin confguration of figure 2 ensures that the width of the so-8 package is used to provide creepage and clearance distance of over 4 mm. although electrical connections are only made to pins 2, 3, 6 and 7, it is recommended that pins 1-4 and pins 5-8 are coupled together on the pcb C see applications section. pi-5608-060810 d package (so-8) nc d1 d1 nc 1 2 3 4 8 7 6 5 nc d2 d2 nc
rev. c 04/11 3 capzero family www.powerint.com key application considerations breakdown voltage selection figure 3 illustrates possible system confgurations infuencing the choice of capzero breakdown voltage. the system confguration variables include the placement of the system mov and x capacitor(s) as well as the differential surge voltage specifcations of the application. as shown in table 1, each device in the capzero family has a 825 v or 1000 v option. for applications where the system mov is placed in position 1 (mov pos1 in figure 3), the 825 v option will typically provide adequate voltage withstand for surge requirements up to 3 kv or more. the 1 kv capzero would be recommended for higher surge requirements or if additional voltage margin is required. for mov placement that is not directly across the x capacitor1 (for example mov pos2 in figure 3) the 1000 v capzero devices can be used up to a surge specifcation of 1.5 kv. for differential surge voltage specifcations of >1.5 kv it is recommended that the mov is always placed in the location shown in figure 3 as mov pos1 . it is always recommended that the peak voltage between terminals d1 and d2 of capzero is measured during surge tests in the fnal system. measurements of peak voltage across capzero during surge tests should be made with oscilloscope probes having appropriate voltage rating and using an isolated supply to the oscilloscope to avoid ground currents infuencing measurement results. when making such measurements, it is recommended that 50 v engineering margin is allowed below the breakdown voltage specifcation (for example 950 v with the 1000 v capzero). figure 3. placement options of mov and c ext . if the measured peak drain voltage exceeds 950 v, an external 1 kv ceramic capacitor of value up to 47 pf can also be placed between d1 and d2 terminals to attenuate the voltage applied between the capzero terminals during surge. this optional external capacitor placement is shown as c ext in figure 3. it should be noted that use of an external capacitor in this way will increase power consumption slightly due to the c ext charge/ discharge currents fowing in r1 and r2 while ac is connected. a c ext value of 33 pf will add approximately 0.5 mw at 230 vac, 50 hz. pcb layout and external resistor selection figure 4 shows a typical pcb layout confguration for capzero. the external resistors in this case are divided into two separate surface mount resistors to distribute loss under fault conditions C for example where a short-circuit exists between capzero terminals d1 and d2. r1 and r2 values are selected according to table 1. under a fault condition where capzero terminals d1 and d2 are shorted together, each resistor will dissipate a power that can be calculated from the applied ac voltage and the r1 and r2 values. for example in an application using cap004 or cap014, r1=r2=390 k w . if capzero is shorted out at 265 vac r1 and r2 will each dissipate 45 mw. resistors r1 and r2 should also be rated for 50% of the system input voltage again to allow for the short-circuitry of capzero d1 to d2 pins during single point fault testing. if lower dissipation or lower voltage across each resistor is required during fault tests, the total external resistance can be divided into more discrete resistors, however the total resistance must be equal to that specifed in table 1. pi-5609-041210 d1 r1 r2 x capacitor1 c ext ac x capacitor2 mov pos1 mov pos2 capzero d2 other emi filter components
rev. c 04/11 4 capzero family www.powerint.com safety capzero meets safety requirements even if placed before the system input fuse. if a short-circuit is placed between d1 and d2 terminals of capzero, the system is identical to existing systems where capzero is not used. with regard to open circuit tests, it is not possible to create a fault condition through a single pin fault (for example lifted pin test) since there are two pins connected to each of d1 and d2. if several pins are lifted to create an open circuit, the condition is identical to an open circuit x capacitor discharge resistor in existing systems where capzero is not used. if redundancy against open circuit faults is required, two capzero and r1 / r2 confgurations can be placed in parallel. discharge operation to meet the safety regulations, when the ac supply is disconnected, capzero will discharge the x capacitor to the safety extra low voltage (selv) levels according to the above functional description. although there are no specifc safety requirements below selv, capzero still continues the discharge until the x capacitor is fully discharged. as such capzero can be safely used at low input voltages such as the common industrial 18 vac and 24 vac supply rails while retaining x capacitor discharge when the ac source is disconnected. figure 4. typical pcb layout. pi-5610-041310 r1 x capacitor r2 �4 mm
rev. c 04/11 5 capzero family www.powerint.com parameter symbol conditions t a = -10 to 105 c (unless otherwise specifed) min typ max units control functions ac removal detection time t detect line cycle frequency 47-63 hz 22 31.4 ms drain saturation current a,b i dsat cap002/012 0.25 ma cap003/013 0.37 cap004/014 0.48 cap005/015 0.78 cap006/016 1.04 cap007/017 1.25 cap008/018 1.88 cap009/019 2.5 supply current i supply t a = 25 c 21.7 m a notes a. saturation current specifcations ensure a natural rc discharge characteristic at all voltages up to 265 vac pk with the external resistor values specifed in component selection table 1. b. specifcations are guaranteed by characterization and design. absolute maximum ratings 4 drain pin voltage 1 cap002-cap009 ..............................825 v cap012-cap019 .............................1000 v drain peak current 2 cap002/cap012 .................... 0.553 ma cap003/cap013 ..................... 0.784 ma cap004/cap014 ..................... 1.026 ma cap005/cap015 ..................... 1.667 ma cap006/cap016 .................... 2.222 ma cap007/cap017 ...................... 2.667 ma cap008/cap018 .................... 4.000 ma cap009/cap019 .................... 5.333 ma storage temperature ...................................... -65 c to 150 c lead temperature 3 .......................................................... 260 c operating ambient temperature ...................... -10 c to 105 c maximum junction temperature ...................... -10 c to 110 c notes: 1. voltage of d1 pin relative to d2 pin in either polarity. 2. the peak drain current is allowed while the drain voltage is simultaneously less than 400 v. 3. 1/16 in. from case for 5 seconds. 4. the absolute maximum ratings specifed may be applied one at a time without causing permanent damage to the product. exposure to absolute maximum rating conditions for extended periods of time may affect product reliability.
rev. c 04/11 6 capzero family www.powerint.com -25 0 25 50 100 75 125 temperature ( c) i supply (normalized to 25 c) 1.20 1.10 1.00 0.90 0.80 0.70 0.60 0.50 0.40 0.30 0.20 0.10 0.00 pi-6020-062110 typical performance characteristics figure 5. i supply vs. temperature.
rev. c 04/11 7 capzero family www.powerint.com pi-5615-041210 d08a so-8 (d package) 3.90 (0.154) bsc notes: 1. jedec reference: ms-012. 2. package outline exclusive of mold flash and metal burr. 3. package outline inclusive of plating thickness. 4. datums a and b to be determined at datum plane h. 5. controlling dimensions are in millimeters. inch dimensions are shown in parenthesis. angles in degrees. 0.20 (0.008) c 2x 1 4 5 8 2 6.00 (0.236) bsc d 4 a 4.90 (0.193) bsc 2 0.10 (0.004) c 2x d 0.10 (0.004) c 2x a-b 1.27 (0.050) bsc 7x 0.31 - 0.51 (0.012 - 0.020) 0.25 (0.010) m c a-b d 0.25 (0.010) 0.10 (0.004) (0.049 - 0.065) 1.25 - 1.65 1.75 (0.069) 1.35 (0.053) 0.10 (0.004) c 7x c h o 1.27 (0.050) 0.40 (0.016) gauge plane 0 - 8 1.04 (0.041) ref 0.25 (0.010) bsc seating plane 0.25 (0.010) 0.17 (0.007) detail a detail a c seating plane pin 1 id b 4 + + + 5.45 (0.215) 1.27 (0.050) 0.60 (0.024) 1.45 (0.057) reference solder pad dimensions + 4.00 (0.157) part ordering information ? capzero product family ? 002 series number ? package identifer d plastic so-8 ? package material g green: halogen free and rohs compliant ? tape & reel and other options blank standard confgurations tl tape & reel, 2.5 k pcs. cap 002 d g - tl
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