0 Watts xxx Series Wide 4: Input Range Single Output Industry Standard /4 Brick -40 C to +0 C Operation 0 VDC Isolation Output Trim ±0% Remote On/Off Year Warranty Dimensions: QSC0:. x.4 x 0. (.9 x. x. mm) Models & Ratings Input Voltage 9- V - V Output Input Current () Ripple & Max. capacitive Output Current Efficiency Voltage noise () Model Number () load No Load Full Load V 0.0 A 0 ma. A 00 mv 9.0% 0000 µf QSC04S0 V. A 0 ma. A 0 mv 9.0% 00 µf QSC04S 4 V. A 0 ma. A 0 mv 9.0% 00 µf QSC04S4 V.4 A 0 ma. A 0 mv 9.% 400 µf QSC04S 4 V. A 0 ma. A 40 mv 9.0% 000 µf QSC04S4 V 0.0 A ma 9. A 00 mv 9.0% 0000 µf QSC04S0 V. A ma 9. A 0 mv 9.0% 00 µf QSC04S 4 V. A ma 9. A 0 mv 90.% 00 µf QSC04S4 V.4 A ma 9. A 0 mv 90.% 400 µf QSC04S 4 V. A ma 9. A 40 mv 9.% 000 µf QSC04S4. At lowest input voltage.. Measured at 0MHz bandwidth and 0uF tant/uf ceramic capacitors on output (0uF electrolytic/uf ceramic capacitors for 4V output).. Measured at nominal input. Mechanical Details.4 (.).0(.) 0.00(.4). (.9).000(0.) BOTTOM VIEW 4 Mounting Holes 0. (.) clearance places 0.00(.) 0.00(.4) 0.040(.0) 0.09(.0) DIA PLACES DIA PLACES 0.min (4.) 0.0 (.) Pin Connections Pin Function +Vin Remote On/Off -Vin 4 -Vout -Sense Trim +Sense +Vout.(4.). All dimensions are in inches (mm). Weight: 0. lbs ( g) approx.. Tolerance: x.xx = ±0.0 (x.x = ±0.) x.xxx = ±0.0 (x.xx = ±0.)
Input Input Voltage Range 9 4 V nominal VDC 4 V nominal Input Current 0/0 A QSC04 at 9 V / QSC04 at V Input Surge 0/00 VDC for 00 ms QSC04 / QSC04 Undervoltage Lockout >.0/../.0./. On: 4 V/4 V VDC <./..0/.0./. Off: 4 V/4 V Lockout Hysteresis 0./0.9 VDC 4 V/4 V Idle Current 0 ma When output is remotely turned off Inrush Current 0. A s As per ETS00 - Recommended Input Fuse 0/ A Time delay fuse - 4 V/4 V Input Reflected Ripple Current 0 ma pk-pk Through µh inductor Output Output Voltage 4 VDC See Models and Ratings table Output Trim ±0 % Initial Set Accuracy ± % At full load and nominal input Minimum Load 0 % No minimum load required Line Regulation ±0. % From minimum to maximum input at full load Load Regulation ±0. % From 0% to full load Transient Response ±.0 % Maximum deviation, recovering to less than % in 0 µs for % step load change. Start Up Time 0 ms Output Voltage Rise Time 0 ms Ripple & Noise mv pk-pk See models and ratings table Overload Protection 0 0 % Short Circuit Protection Continuous hiccup mode, with auto recovery Maximum Capacitive Load See Models and Ratings table Temperature Coefficient 0.0 %/ C Overvoltage Protection 40 % Remote On/Off Output is on if remote on/off (pin ) is open or high (.- VDC) Output turns off if remote on/off (pin ) is low (<. VDC max) General Efficiency 9 % See Models and Ratings table Isolation: Input to Output 0 VDC 0 s Isolation: Input and output to Case 0 VDC 0 s Switching Frequency /00 khz 4S model / All other models Isolation Resistance 0 9 Ω Isolation Capacitance 00 pf Power Density 90. W/in Mean Time Between Failure 09/ khrs S0/S4, MIL-HDBK-F, + C GB Weight 0. (.0) lb (g) Environmental Operating Base Plate Temperature -40 +0 C Storage Temperature - + C Thermal Protection +0 C Operating Altitude 000 m Humidity 9 %RH Non-condensing Cooling Base plate cooled
Safety Approvals Agency Standard & Conditions UL cul090- ITE EMC: Emissions Phenomenon Standard Test Level & Conditions Conducted EN0 Class A See Application Radiated EN0 Class A EMC: Immunity Phenomenon Standard Test Level Criteria & Conditions ESD Immunity EN000-4- ± kv/± kv A Contact Discharge/Air Discharge Radiated Immunity EN000-4- 0 V/m A EFT/Burst EN000-4-4 kv A With 40 µf/00 V electrolytic on input Surge EN000-4- kv A External TVS, SMCJA and 40 µf/00 V on input Conducted Immunity EN000-4- 0 V rms A Magnetic Fields EN000-4- A/m A Mechanical Details. (.9).000(0.) Mounting Holes 0. (.) clearance places.4 (.).0(.) 0.00(.4) BOTTOM VIEW 4 0.00(.) 0.00(.4).(4.) 0.040(.0) 0.09(.0) DIA PLACES DIA PLACES 0.min (4.) 0.0 (.) Pin Connections Pin Function +Vin Remote On/Off -Vin 4 -Vout -Sense Trim +Sense +Vout. All dimensions are in inches (mm). Weight: 0. lbs ( g) approx.. Tolerance: x.xx = ±0.0 (x.x = ±0.) x.xxx = ±0.0 (x.xx = ±0.)
Application Input Fusing and Safety Considerations The QSC0 series converters have no internal fuse. In order to achieve maximum safety and system protection, always use an input line fuse. We recommended a 0 A time delay fuse for nominal 4 V and A time delay fuse for nominal 4 V. It is recommended that the circuit has a transient voltage suppressor diode (TVS) across the input terminals to protect the unit against surge or spike voltages and input reverse voltage (as shown). A suitable part would be SMCJA. Fuse +Vin +Vout 9 Vin + - TVS Remote On/Off +Sense Trim -Sense RD RU Load -Vin -Vout Output Voltage Adjustment The Trim input permits the user to adjust the output voltage up or down 0%. This is accomplished by connecting an external resistor between the Trim pin and either the +Sense pin or the -Sense pin. To Trim Down Connecting an external resistor (R D ) between the Trim pin and the Vout (+) (or +Sense) pin decreases the output voltage. The following table can be used to determine the required external resistor (R D ) value to obtain a percentage output voltage change of Δ%. To Trim Up Connecting an external resistor (R U ) between the Trim pin and the Vout (-) (or -Sense) pin increases the output voltage. The following table can be used to determine the required external resistor (R U ) value to obtain a percentage output voltage change of Δ%. RD (kω) Trim Down % V V 4 V V 4 V % 0.400 0.0.00 94.00 0.00 %.0 00.0.0 90.0 400.00 %.00 0.00 4.0 4.0.0 4%.0 0.00.90.90 4.0 %.0.99.0.00.0 %.0 9.9.0.00.0 % 0.90 4..00 4.0.0 %.0 9.9 04.00 9.0 0.0 9%.9 9.9 9.0.. 0%.90.94 9. 4.4. RU (kω) Trim Up % V V 4 V V 4 V %.00.0.0.0 4.0 % 4.00 4.0 9... %.0 4.99 0.. 4. 4%.00 4..9.0.40 % 9.900.94... %.00..0.0 0.0 %.0.9.9.9.94 %.00.0 4.. 4.0 9% 9.9.9..40.0 0%.00. 0.9.4 0. 4
Thermal Resistance Information Airflow Derating Graph - Without Heatsink Power Dissipated vs Ambient Temperature and Air Flow without heatsink Power Disspated,Pd(Watts) Natural Convection 0 ft./min. (0. m/s) 00 ft./min. (0. m/s) 00 ft./min. (.0 m/s) 00 ft./min. (. m/s) Air Flow Rate Typical Rca Natural Convection 0 ft/min (0. m/s) 0. C/W 00 ft/min (0. m/s).0 C/W 00 ft/min (.0 m/s).4 C/W 00 ft/min (. m/s) 4.4 C/W 400 ft/min (.0 m/s).4 C/W 400 ft./min. (.0 m/s) Ambient Temperature,Ta(De g. C) Example (Without Heatsink) To determine the minimum airflow necessary for a QS04S operating at an input voltage of 4 V, an output current of. A, and a maximum ambient temperature of 40 C: Determine Power dissipation (Pd): Pd = Pi-Po = Po(-η)/η, Pd = V. A (-0.9)/0.9 =. Watts Where Pi = Input power, Po = Output Power and η = Efficiency Determine airflow from airflow derating graph using data points for Pd=. W and Ta = 40 C Minimum airflow= 400 ft./min. To check that the maximum case temp of 0 C is not exceeded: Maximum temperature rise is ΔT = Pd Rca =..4 =. C. Maximum case temperature is Tc=Ta+ΔT=9. C <0 C. Where: Rca is the thermal resistance from case to ambient environment. Ta is ambient temperature and Tc is case temperature. Conducted Emissions +Vin -Vin L C L C C +Vin +Vo QSC0 -Vin -Vo C4 +Vout -Vout Model Number C C C C4 L L QSC04S0 40 µf/0 V 40 µf/0 V 00 pf 00 pf Short 0.mH QSC04S 40 µf/0 V 40 µf/0 V 00 pf 00 pf Short 0.mH QSC04S4 40 µf/0 V 40 µf/0 V 00 pf 00 pf Short 0.mH QSC04S 40 µf/0 V 40 µf/0 V 00 pf 00 pf Short 0.mH QSC04S4 40 µf/0 V 40 µf/0 V 400 pf 400 pf Short 0.mH QSC04S0 0 µf/00 V 0 µf/00 V 00 pf 00 pf Short 0.mH QSC04S 0 µf/00 V 0 µf/00 V 00 pf 00 pf Short 0.mH QSC04S4 0 µf/00 V 0 µf/00 V 00 pf 00 pf Short 0.mH QSC04S 0 µf/00 V 0 µf/00 V 00 pf 00 pf Short 0.mH QSC04S4 0 µf/00 V 0 µf/00 V 400 pf 400 pf Short 0.mH Note: C, C are NIPPON CHEMI-CON KY series aluminum capacitors, C, C4 are ceramic capacitors. 9 Nov