AEE15WM Series 15 Watts DC/DC Converter AEE15WM Series Page 1 Total Power: 15 Watts Input Voltage: 9 to 18 18 to 36 36 to 75 # of Outputs: Single, Dual Special Features 4200 VAC reinforced insulation Insulation rated for 300 VAC working voltage Medical safety to UL/CSA/EN/IEC 606011 3 rd edition 2 *MOPP rated Wide 2:1 input voltage range Fully regulated output voltage No min. load requirement Overload/Voltage and Short Circuit Protection Low leakage current <5 µa Operating temperature range 40 O C to +80 O C (with derating) Input filter meets EN55022, Class A and FCC, Level A 2 x 1 plastic package 3 Years product warranty Product Descriptions The AEE15WM series is the new range of high performance DCDC converter with a reinforced insulation system. I/O isolation voltage is specified for 4200VACrms. The product comes in a compact 2 x1 industry standard package. All models provide wide 2:1 input voltage range and fully regulated output voltage regulation. The AEE15WM series DC/DC converters offer an economical solution for demanding applications in industrial and medical instrumentation requesting a certified supplementary or reinforced insulation system to comply with industrial or latest medical safety standards. Safety EN/IEC606011 3 rd Edition, ANSI/AAMI ES606011 UL/cUL/IEC/ EN623681 (609501), 2 *MOPP CE Mark
Model Numbers AEE15WM Series Page 2 Model Input Voltage Output Voltage Maximum Load Efficiency AEE03A12M 9 18 5 3A 85 AEE01B12M 9 18 12 1.25A 89 AEE01C12M 9 18 15 1A 88 AEE01H12M 9 18 24 0.625A 88 AEE01BB12M 9 18 ±12 ±0.625A 88 AEE01CC12M 9 18 ±15 ±0.5A 89 AEE03A24M 18 36 5 3A 87 AEE01B24M 18 36 12 1.25A 89 AEE01C24M 18 36 15 1A 88 AEE01H24M 18 36 24 0.625A 90 AEE01BB24M 18 36 ±12 ±0.625A 90 AEE01CC24M 18 36 ±15 ±0.5A 89 AEE03A48M 36 75 5 3A 88 AEE01B48M 36 75 12 1.25A 88 AEE01C48M 36 75 15 1A 87 AEE01H48M 36 75 24 0.625A 88 AEE01BB48M 36 75 ±12 ±0.625A 88 AEE01CC48M 36 75 ±15 ±0.5A 88 Options None
Electrical Specifications AEE15WM Series Page 3 Absolute Maximum Ratings Stress in excess of those listed in the Absolute Maximum Ratings may cause permanent damage to the power supply. These are stress ratings only and functional operation of the unit is not implied at these or any other conditions above those given in the operational sections of this TRN. Exposure to any absolute maximum rated condition for extended periods may adversely affect the power supply s reliability. Table 1. Absolute Maximum Ratings: Parameter Model Symbol Min Typ Max Unit Input Surge Voltage ms. max 12V Input Models 24V Input Models 48V Input Models V IN,DC 0.7 0.7 0.7 Maximum Output Power All Models P O,max 15 W Isolation Voltage Input to Output (60 seconds) All Models 4200 Vac Isolation Resistance (500) All Models 10 Gohm Isolation Capacitance (KHz,1V) All Models 80 pf Thermal Impedance Natural Convection 13 O C/W Operating Ambient Temperature Range Natural Convection 40 +80 1 O C Operating Case Temperature All Models T CASE +95 O C Storage Temperature All Models T STG 50 +125 O C 25 50 Humidity (noncondensing) Operating Nonoperating All Models 95 95 MTBF MILHDBK 217F@25 O C, Ground Benign 0000 Hours Note 1 With Derating
Input Specifications AEE15WM Series Page 4 Table 2. Input Specifications: Parameter Condition Symbol Min Nom Max Unit Operating Input Voltage, DC 12V Input Models 24V Input Models 48V Input Models All V IN,DC 18 9 36 12 24 48 18 36 75 StartUp Threshold Voltage 12V Input Models 24V Input Models 48V Input Models All V IN,ON 9 18 36 Under Voltage Lockout 12V Input Models 24V Input Models 48V Input Models All V IN,OFF 7.5 15 33 Input reflected ripple current 12V Input Models 24V Input Models 48V Input Models 0 to 500KHz, Lin=4.7µH Cin=220uF, ESR< 1.0Ω at KHz I IN,ripple 50 30 Input Current AEE03A12M AEE01B12M AEE01C12M AEE01H12M AEE01BB12M AEE01CC12M AEE03A24M AEE01B24M AEE01C24M AEE01H24M AEE01BB24M AEE01CC24M AEE03A48M AEE01B48M AEE01C48M AEE01H48M AEE01BB48M AEE01CC48M V IN,DC =V IN,nom I O =I O,max I IN,max_load 1471 1404 1420 1420 1420 1404 718 702 710 694 694 702 355 355 359 355 355 355 No Load Input Current (V O On, I O = 0A) 12V Input Models 24V Input Models 48V Input Models V IN,DC =V IN,nom I IN,no_load 20 15 10
Input Specifications AEE15WM Series Page 5 Table 2. Input Specifications con t: Parameter Condition Symbol Min Nom Max Unit Efficiency @Max. Load AEE03A12M AEE01B12M AEE01C12M AEE01H12M AEE01BB12M AEE01CC12M AEE03A24M AEE01B24M AEE01C24M AEE01H24M AEE01BB24M AEE01CC24M AEE03A48M AEE01B48M AEE01C48M AEE01H48M AEE01BB48M AEE01CC48M V IN,DC =V IN,nom I O =I O,max T A =25 O C η 85 89 88 88 88 89 87 89 88 90 90 89 88 88 87 88 88 88 Leakage Current V IN,AC =240Vac f IN =60Hz l IN,Leakage 5 µa Internal Filter Type All Internal Pi Type
Output Specifications AEE15WM Series Page 6 Table 3. Output Specifications: Parameter Condition Symbol Min Nom Max Unit Output Voltage Set Point V IN,DC= V IN,nom I O =I O, max T A =25 O C V O 1 Output Voltage Balance Output Current V O Load Capacitance Dual Output, Balanced Loads AEE03A12M AEE01B12M AEE01C12M AEE01H12M AEE01BB12M AEE01CC12M AEE03A24M AEE01B24M AEE01C24M AEE01H24M AEE01BB24M AEE01CC24M AEE03A48M AEE01B48M AEE01C48M AEE01H48M AEE01BB48M AEE01CC48M AEE03A12M AEE01B12M AEE01C12M AEE01H12M AEE01BB12M AEE01CC12M AEE03A24M AEE01B24M AEE01C24M AEE01H24M AEE01BB24M AEE01CC24M AEE03A48M AEE01B48M AEE01C48M AEE01H48M AEE01BB48M AEE01CC48M All ±V O 2.0 Natural Convection All I O C O 3 1.25 1 0.625 ±0.625 ±0.5 3 1.25 1 0.625 ±0.625 ±0.5 3 1.25 1 0.625 ±0.625 ±0.5 5 870 560 220 440 1 280 1 5 870 560 220 440 1 280 1 5 870 560 220 440 1 280 1 A A A A A A A A A A A A A A A A A A uf uf uf uf uf uf uf uf uf uf uf uf uf uf uf uf uf uf
Output Specifications AEE15WM Series Page 7 Table 3. Output Specifications con t: Parameter Condition Symbol Min Nom Max Unit Start Up Time V IN,DC =V IN,nom I O =I O,max Resistive Load T TurnOn 30 msec Line Regulation Load Regulation Single Output Dual Output V IN,DC =V IN,min to V IN,max I O =I O,max ±V O 0.5 I O =I O,min to I O,max ±V O Switching Frequency All f SW 285 KHz V O Dynamic Response Peak Deviation Settling Time 25 load change ±V O t s Temperature Coefficient All / O C 0.02 0.02 Output Over Current Protection 2 All I O,max 150 Output Short Circuit Protection 3 All Hiccup Automatic Recovery ±3 0.5 1.0 ±5 300 usec Output Over Voltage Protection AEE03A12M AEE01B12M AEE01C12M AEE01H12M AEE01BB12M AEE01CC12M AEE03A24M AEE01B24M AEE01C24M AEE01H24M AEE01BB24M AEE01CC24M AEE03A48M AEE01B48M AEE01C48M AEE01H48M AEE01BB48M AEE01CC48M All 6.2 15 18 27 ±15 ±18 6.2 15 18 27 ±15 ±18 6.2 15 18 27 ±15 ±18 Note 1 For each output Note 2 Hiccup Automatic Recovery Note 3 Hiccup Mode 0.7Hz typ., Automatic Recovery
Output Specifications AEE15WM Series Page 8 Table 3. Output Specifications con t: Parameter Condition Symbol Min Nom Max Unit Output Ripple, pkpk AEE03A12M AEE03A24M AEE03A48M AEE01B12M AEE01C12M AEE01BB12M AEE01CC12M AEE01B24M AEE01C24M AEE01BB24M AEE01CC24M AEE01B48M AEE01C48M AEE01BB48M AEE01CC48M AEE01H12M AEE01H24M AEE01H48M Measure with a 4.7uF ceramic capacitor in parallel with a 10uF tantalum capacitor, 0 to 20MHz bandwidth V O 5 5 5 150 150 150 mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK mv PKPK
AEE03A12M Performance Curves AEE15WM Series Page 9 Figure 1: AEE03A12M Efficiency Versus Output Current Curve Vin = 9 to 18, Io = 0 to 3A, Ta = 25 O C Figure 2: AEE03A12M Efficiency Versus Input Voltage Curve Vin = 9 to 18, Io = 3A, Ta = 25 O C Figure 3: AEE03A12M Ripple and Noise Measurement Vin = 12, Io = 3A, Ta = 25 O C Figure 4: AEE03A12M Transient Response Vin = 12, Io = to 75 of full load change, Ta = 25 O C Figure 5: AEE03A12M Output Voltage Startup Characteristic by Vin Vin = 12, Io = 3A, Ta = 25 O C Ch 3: Vin Figure 6: AEE03A12M Derating Curve (without heatsink) Vin = 12, Io = 0 to 3A, Ta = 25 O C
AEE01B12M Performance Curves AEE15WM Series Page 10 Figure 7: AEE01B12M Efficiency Versus Output Current Curve Vin = 9 to 18, Io = 0 to 1.25A, Ta = 25 O C Figure 8: AEE01B12M Efficiency Versus Input Voltage Curve Vin = 9 to 18, Io = 1.25A, Ta = 25 O C Figure 9: AEE01B12M Ripple and Noise Measurement Vin = 12, Io = 1.25A, Ta = 25 O C Figure 10: AEE01B12M Transient Response Vin = 12, Io = to 75 of full load change, Ta = 25 O C 80 60 Natural Convection 20LFM 40 20 0 ~ 40 0 20 40 60 80 110 Ambient Temperature C Figure 11: AEE01B12M Output Voltage Startup Characteristic by Vin Vin = 12, Io = 1.25A, Ta = 25 O C Ch 3: Vin Figure 12: AEE01B12M Derating Curve (without heatsink) Vin = 12, Io = 0 to 1.25A, Ta = 25 O C
AEE01C12M Performance Curves AEE15WM Series Page 11 Figure 13: AEE01C12M Efficiency Versus Output Current Curve Vin = 9 to 18, Io = 0 to 1A, Ta = 25 O C Figure 14: AEE01C12M Efficiency Versus Input Voltage Curve Vin = 9 to 18, Io = 1A, Ta = 25 O C Figure 15: AEE01C12M Ripple and Noise Measurement Vin = 12, Io = 1A, Ta = 25 O C Figure 16: AEE01C12M Transient Response Vin = 12, Io = to 75 of full load change, Ta = 25 O C Figure 17: AEE01C12M Output Voltage Startup Characteristic by Vin Vin = 12, Io = 1A, Ta = 25 O C Ch 3: Vin Figure 18: AEE01C12M Derating Curve (without heatsink) Vin = 12, Io = 0 to 1A, Ta = 25 O C
AEE01H12M Performance Curves AEE15WM Series Page 12 Figure 19: AEE01H12M Efficiency Versus Output Current Curve Vin = 9 to 18, Io = 0 to 0.625A, Ta = 25 O C Figure 20: AEE01H12M Efficiency Versus Input Voltage Curve Vin = 9 to 18, Io = 0.625A, Ta = 25 O C Figure 21: AEE01H12M Ripple and Noise Measurement Vin = 12, Io = 0.625A, Ta = 25 O C Figure 22: AEE01H12M Transient Response Vin = 12, Io = to 75 of full load change, Ta = 25 O C 80 60 Natural Convection 20LFM 40 20 0 ~ 40 0 20 40 60 80 110 Ambient Temperature C Figure 23: AEE01H12M Output Voltage Startup Characteristic by Vin Vin = 12, Io = 0.625A, Ta = 25 O C Ch 3: Vin Figure 24: AEE01H12M Derating Curve (without heatsink) Vin = 12, Io = 0 to 0.625A, Ta = 25 O C
AEE01BB12M Performance Curves AEE15WM Series Page 13 Figure 25: AEE01BB12M Efficiency Versus Output Current Curve Vin = 9 to 18, Io = 0 to ±0.625A, Ta = 25 O C Figure 26: AEE01BB12M Efficiency Versus Input Voltage Curve Vin = 9 to 18, Io = ±0.625A, Ta = 25 O C Figure 27: AEE01BB12M Ripple and Noise Measurement Vin = 12, Io = ±0.625A, Ta = 25 O C 1 Ch 2: Vo2 Figure 28: AEE01BB12M Transient Response Vin = 12, Io = to 75 of full load change, Ta = 25 O C 1 Ch 2: Vo2 Figure 29: AEE01BB12M Output Voltage Startup Characteristic by Vin Vin = 12, Io = ±0.625A, Ta = 25 O C 1 Ch 2: Vo2 Ch 3: Vin Figure 30: AEE01BB12M Derating Curve (without heatsink) Vin = 12, Io = 0 to ±0.625A, Ta = 25 O C
AEE01CC12M Performance Curves AEE15WM Series Page 14 Figure 31: AEE01CC12M Efficiency Versus Output Current Curve Vin = 9 to 18, Io = 0 to ±0.5A, Ta = 25 O C Figure 32: AEE01CC12M Efficiency Versus Input Voltage Curve Vin = 9 to 18, Io = ±0.5A, Ta = 25 O C Figure 33: AEE01CC12M Ripple and Noise Measurement Vin = 12, Io = ±0.5A, Ta = 25 O C 1 Ch 2: Vo2 Figure 34: AEE01CC12M Transient Response Vin = 12, Io = to 75 of full load change, Ta = 25 O C 1 Ch 2: Vo2 Figure 35: AEE01CC12M Output Voltage Startup Characteristic by Vin Vin = 12, Io = ±0.5A, Ta = 25 O C 1 Ch 2: Vo2 Ch 3: Vin Figure 36: AEE01CC12M Derating Curve (without heatsink) Vin = 12, Io = 0 to ±0.5A, Ta = 25 O C
AEE03A24M Performance Curves AEE15WM Series Page 15 Figure 37: AEE03A24M Efficiency Versus Output Current Curve Vin = 18 to 36, Io = 0 to 3A, Ta = 25 O C Figure 38: AEE03A24M Efficiency Versus Input Voltage Curve Vin = 18 to 36, Io = 3A, Ta = 25 O C Figure 39: AEE03A24M Ripple and Noise Measurement Vin = 24, Io = 3A, Ta = 25 O C Figure 40: AEE03A24M Transient Response Vin = 24, Io = to 75 of full load change, Ta = 25 O C Figure 41: AEE03A24M Output Voltage Startup Characteristic by Vin Vin = 24, Io = 3A, Ta = 25 O C Ch 3: Vin Figure 42: AEE03A24M Derating Curve (without heatsink) Vin = 24, Io = 0 to 3A, Ta = 25 O C
AEE01B24M Performance Curves AEE15WM Series Page 16 Figure 43: AEE01B24M Efficiency Versus Output Current Curve Vin = 18 to 36, Io = 0 to 1.25A, Ta = 25 O C Figure 44: AEE01B24M Efficiency Versus Input Voltage Curve Vin = 18 to 36, Io = 1.25A, Ta = 25 O C Figure 45: AEE01B24M Ripple and Noise Measurement Vin = 24, Io = 1.25A, Ta = 25 O C Figure 46: AEE01B24M Transient Response Vin = 24, Io = to 75 of full load change, Ta = 25 O C Figure 47: AEE01B24M Output Voltage Startup Characteristic by Vin Vin = 24, Io = 1.25A, Ta = 25 O C Ch 3: Vin Figure 48: AEE01B24M Derating Curve (without heatsink) Vin = 24, Io = 0 to 1.25A, Ta = 25 O C
AEE01C24M Performance Curves AEE15WM Series Page 17 Figure 49: AEE01C24M Efficiency Versus Output Current Curve Vin = 18 to 36, Io = 0 to 1A, Ta = 25 O C Figure 50: AEE01C24M Efficiency Versus Input Voltage Curve Vin = 18 to 36, Io = 1A, Ta = 25 O C Figure 51: AEE01C24M Ripple and Noise Measurement Vin = 24, Io = 1A, Ta = 25 O C Figure 52: AEE01C24M Transient Response Vin = 24, Io = to 75 of full load change, Ta = 25 O C Figure 53: AEE01C24M Output Voltage Startup Characteristic by Vin Vin = 24, Io = 1A, Ta = 25 O C Ch 3: Vin Figure 54: AEE01C24M Derating Curve (without heatsink) Vin = 24, Io = 0 to 1A, Ta = 25 O C
AEE01H24M Performance Curves AEE15WM Series Page 18 Figure 55: AEE01H24M Efficiency Versus Output Current Curve Vin = 18 to 36, Io = 0 to 0.625A, Ta = 25 O C Figure 56: AEE01H24M Efficiency Versus Input Voltage Curve Vin = 18 to 36, Io = 0.625A, Ta = 25 O C Figure 57: AEE01H24M Ripple and Noise Measurement Vin = 24, Io = 0.625A, Ta = 25 O C Figure 58: AEE01H24M Transient Response Vin = 24, Io = to 75 of full load change, Ta = 25 O C Figure 59: AEE01H24M Output Voltage Startup Characteristic by Vin Vin = 24, Io = 0.625A, Ta = 25 O C Ch 3: Vin Figure 60: AEE01H24M Derating Curve (without heatsink) Vin = 24, Io = 0 to 0.625A, Ta = 25 O C
AEE01BB24M Performance Curves AEE15WM Series Page 19 Figure 61: AEE01BB24M Efficiency Versus Output Current Curve Vin = 18 to 36, Io = 0 to ±0.625A, Ta = 25 O C Figure 62: AEE01BB24M Efficiency Versus Input Voltage Curve Vin = 18 to 36, Io = ±0.625A, Ta = 25 O C Figure 63: AEE01BB24M Ripple and Noise Measurement Vin = 24, Io = ±0.625A, Ta = 25 O C 1 Ch 2: Vo2 Figure 64: AEE01BB24M Transient Response Vin = 24, Io = to 75 of full load change, Ta = 25 O C 1 Ch 2: Vo2 80 60 Natural Convection 20LFM 40 20 0 ~ 40 0 20 40 60 80 110 Ambient Temperature C Figure 65: AEE01BB24M Output Voltage Startup Characteristic by Vin Vin = 24, Io = ±0.625A, Ta = 25 O C 1 Ch 2: Vo2 Ch 3: Vin Figure 66: AEE01BB24M Derating Curve (without heatsink) Vin = 24, Io = 0 to ±0.625A, Ta = 25 O C
AEE01CC24M Performance Curves AEE15WM Series Page 20 Figure 67: AEE01CC24M Efficiency Versus Output Current Curve Vin = 18 to 36, Io = 0 to ±0.5A, Ta = 25 O C Figure 68: AEE01CC24M Efficiency Versus Input Voltage Curve Vin = 18 to 36, Io = ±0.5A, Ta = 25 O C Figure 69: AEE01CC24M Ripple and Noise Measurement Vin = 24, Io = ±0.5A, Ta = 25 O C 1 Ch 2: Vo2 Figure 70: AEE01CC24M Transient Response Vin = 24, Io = to 75 of full load change, Ta = 25 O C 1 Ch 2: Vo2 Figure 71: AEE01CC24M Output Voltage Startup Characteristic by Vin Vin = 24, Io = ±0.5A, Ta = 25 O C 1 Ch 2: Vo2 Ch 3: Vin Figure 72: AEE01CC24M Derating Curve (without heatsink) Vin = 24, Io = 0 to ±0.5A, Ta = 25 O C
AEE03A48M Performance Curves AEE15WM Series Page 21 Figure 73: AEE03A48M Efficiency Versus Output Current Curve Vin = 36 to 75, Io = 0 to 3A, Ta = 25 O C Figure 74: AEE03A48M Efficiency Versus Input Voltage Curve Vin = 36 to 75, Io = 3A, Ta = 25 O C Figure 75: AEE03A48M Ripple and Noise Measurement Vin = 48, Io = 3A, Ta = 25 O C Figure 76: AEE03A48M Transient Response Vin = 48, Io = to 75 of full load change, Ta = 25 O C 80 60 Natural Convection 20LFM 40 20 0 ~ 40 0 20 40 60 80 110 Ambient Temperature C Figure 77: AEE03A48M Output Voltage Startup Characteristic by Vin Vin = 48, Io = 3A, Ta = 25 O C Ch 3: Vin Figure 78: AEE03A48M Derating Curve (without heatsink) Vin = 48, Io = 0 to 3A, Ta = 25 O C
AEE01B48M Performance Curves AEE15WM Series Page 22 Figure 79: AEE01B48M Efficiency Versus Output Current Curve Vin = 36 to 75, Io = 0 to 1.25A, Ta = 25 O C Figure 80: AEE01B48M Efficiency Versus Input Voltage Curve Vin = 36 to 75, Io = 1.25A, Ta = 25 O C Figure 81: AEE01B48M Ripple and Noise Measurement Vin = 48, Io = 1.25A, Ta = 25 O C Figure 82: AEE01B48M Transient Response Vin = 48, Io = to 75 of full load change, Ta = 25 O C 80 60 Natural Convection 20LFM 40 20 0 ~ 40 0 20 40 60 80 110 Ambient Temperature C Figure 83: AEE01B48M Output Voltage Startup Characteristic by Vin Vin = 48, Io = 1.25A, Ta = 25 O C Ch 3: Vin Figure 84: AEE01B48M Derating Curve (without heatsink) Vin = 48, Io = 0 to 1.25A, Ta = 25 O C
AEE01C48M Performance Curves AEE15WM Series Page 23 Figure 85: AEE01C48M Efficiency Versus Output Current Curve Vin = 36 to 75, Io = 0 to 1A, Ta = 25 O C Figure 86: AEE01C48M Efficiency Versus Input Voltage Curve Vin = 36 to 75, Io = 1A, Ta = 25 O C Figure 87: AEE01C48M Ripple and Noise Measurement Vin = 48, Io = 1A, Ta = 25 O C Figure 88: AEE01C48M Transient Response Vin = 48, Io = to 75 of full load change, Ta = 25 O C Figure 89: AEE01C48M Output Voltage Startup Characteristic by Vin Vin = 48, Io = 1A, Ta = 25 O C Ch 3: Vin Figure 90: AEE01C48M Derating Curve (without heatsink) Vin = 48, Io = 0 to 1A, Ta = 25 O C
AEE01H48M Performance Curves AEE15WM Series Page 24 Figure 91: AEE01H48M Efficiency Versus Output Current Curve Vin = 36 to 75, Io = 0 to 0.625A, Ta = 25 O C Figure 92: AEE01H48M Efficiency Versus Input Voltage Curve Vin = 36 to 75, Io = 0.625A, Ta = 25 O C Figure 93: AEE01H48M Ripple and Noise Measurement Vin = 48, Io = 0.625A, Ta = 25 O C Figure 94: AEE01H48M Transient Response Vin = 48, Io = to 75 of full load change, Ta = 25 O C Figure 95: AEE01H48M Output Voltage Startup Characteristic by Vin Vin = 48, Io = 0.625A, Ta = 25 O C Ch 3: Vin Figure 96: AEE01H48M Derating Curve (without heatsink) Vin = 48, Io = 0 to 0.625A, Ta = 25 O C
AEE01BB48M Performance Curves AEE15WM Series Page 25 Figure 97: AEE01BB48M Efficiency Versus Output Current Curve Vin = 36 to 75, Io = 0 to ±0.625A, Ta = 25 O C Figure 98: AEE01BB48M Efficiency Versus Input Voltage Curve Vin = 36 to 75, Io = ±0.625A, Ta = 25 O C Figure 99: AEE01BB48M Ripple and Noise Measurement Vin = 48, Io = ±0.625A, Ta = 25 O C 1 Ch 2: Vo2 Figure : AEE01BB48M Transient Response Vin = 48, Io = to 75 of full load change, Ta = 25 O C 1 Ch 2: Vo2 Figure 101: AEE01BB48M Output Voltage Startup Characteristic by Vin Vin = 48, Io = ±0.625A, Ta = 25 O C 1 Ch 2: Vo2 Ch 3: Vin Figure 102: AEE01BB48M Derating Curve (without heatsink) Vin = 48, Io = 0 to ±0.625A, Ta = 25 O C
AEE01CC48M Performance Curves AEE15WM Series Page 26 Figure 103: AEE01CC48M Efficiency Versus Output Current Curve Vin = 36 to 75, Io = 0 to ±0.5A, Ta = 25 O C Figure 104: AEE01CC48M Efficiency Versus Input Voltage Curve Vin = 36 to 75, Io = ±0.5A, Ta = 25 O C Figure 104: AEE01CC48M Ripple and Noise Measurement Vin = 48, Io = ±0.5A, Ta = 25 O C 1 Ch 2: Vo2 Figure 105: AEE01CC48M Transient Responses Vin = 48, Io = to 75 of full load change, Ta = 25OC 1 Ch 2: Vo2 80 60 Natural Convection 20LFM 40 20 0 ~ 40 0 20 40 60 80 110 Ambient Temperature C Figure 106: AEE01CC48M Output Voltage Startup Characteristic by Vin Vin = 48, Io = ±0.5A, Ta = 25 O C 1 Ch 2: Vo2 Ch 3: Vin Figure 107: AEE01CC48M Derating Curve (without heatsink) Vin = 48, Io = 0 to ±0.5A, Ta = 25 O C
Mechanical Specifications AEE15WM Series Page 27 Mechanical Outlines Pin Connections 5.08 5.08 [0.20] [0.20] 2 1 2.54 [0.10] 1.00 [ 0.04] Single output Pin 1 +Vin Pin 2 Vin Bottom View 45.72 [1.80] 50.8 [2.00] Pin 3 +Vout Pin 4 No Pin Pin 5 Vout 5 4 3 Dual Output 10.16 [0.40] 10.16 [0.40] 2.54 [0.10] 5.08 [0.20] 12.0 [0.47] Pin 1 +Vin 25.4 [1.00] Pin 2 Vin Note: 1.All dimensions in mm (inches) 2.Tolerance: X.X±0.5 (X.XX±0.02) X.XX±0.25 ( X.XXX±0.01) 3.Pin diameter 0.5 ±0.05 (0.02±0.002) Pin 3 +Vout Pin 4 Common Pin 5 Vout Physical Characteristics Case Size ESD Radiated immunity Fast transient 1 50.8x25.4x12.0mm (2.0x1.0x0.47 inches) NonConductive Black Plastic (flammability to UL 94V0 rated) Tinned Copper 30g
Recommended Pad Layout AEE15WM Series Page 28 5.08 [0.20] 5.08 [0.20] 5X 1.8 0.1(PAD)[5X 0.07 0.004] 5X 1.3 0.1(HOLE)[5X 0.05 0.004] 1 2 50.8 [2.00] 45.72 [1.80] Top View 3 4 5 2.54 [0.1] 10.16 [0.40] 10.16 [0.40] 25.4 [1.00]
Environmental Specifications AEE15WM Series Page 29 EMC Immunity AEE15WM series power supply is designed to meet the following EMC immunity specifications. Table 4. EMC Specifications: Parameter Standards & Level Performance EMI Conduction EN55022, EN55032, EN55022, FCC part15 Class A EN6060112, EN55024 ESD Radiated immunity EN6042 Air ±8kV, Contact ±6kV EN6043 10V/m Perf. Criteria A EMS Fast transient 1 EN6044 ±2KV Perf. Criteria A Surge 1 EN6045 ±1KV Perf. Criteria A Conducted immunity EN6046 10Vrms Perf. Criteria A PFMF EN6048 3A/M Perf. Criteria A Note 1: To meet EN6044 & EN6045, an external capacitor across the input pins is required.
Safety Certifications AEE15WM Series Page 30 The AEE15WM series power supply is intended for inclusion in other equipment and the installer must ensure that it is in compliance with all the requirements of the end application. This product is only for inclusion by professional installers within other equipment and must not be operated as a stand alone product. Table 5. Safety Certifications for AEE15WM series power supply system: Document cul/ul 609501, CSA C22.2 No. 609501 ANSI/AAMI ES606011, CAN/CSA C22.2 No. 606011 IEC/EN 609501, IEC/EN 626381, IEC/EN 606011 3 rd Edition 2 *MOPP Description US and Canada Requirements International and Canada Medical Requirements International and European Medical Requirements
Operating Temperature AEE15WM Series Page 31 Table 6. Operating Temperature: Parameter Model / Condition Min Max Unit AEE01H24M AEE01BB24M +73 AEE01B12M AEE01CC12M AEE01B24M AEE01CC24M +70 Operating Temperature Range (Natural Convection 1, See Derating) AEE01C12M AEE01H12M AEE01BB12M AEE01C24M AEE03A48M AEE01B48M AEE01H48M AEE01BB48M AEE01CC48M 40 +67 O C AEE03A24M AEE01C48M +65 AEE03A12M +59 Operating Case Temperature All +95 O C Thermal Impedance (Natural Convection 1 ) 13 O C/W Storage Temperature Range 50 +125 O C Humidity (noncondensing) 95 Altitude 4000 m Cooling Natural Convection 1 Lead Temperature (1.5mm from case for 10Sec.) 260 O C Note1 The Natural Convection is about 20LFM but is not equal to still air (0LFM).
MTBF and Reliability AEE15WM Series Page 32 The MTBF of AEE15WM series of DC/DC converters has been calculated using MILHDBK 217F NOTICE2, Operating Temperature 25 O C, Ground Benign. Model MTBF Unit AEE03A12M 1,428,181 AEE01B12M 1,927,407 AEE01C12M 2,026,516 AEE01H12M 1,780,163 AEE01BB12M 1,780,163 AEE01CC12M 2,108,738 AEE03A24M 1,646,820 AEE01B24M 1,975,949 AEE01C24M 2,068,481 AEE01H24M 2,019,674 AEE01BB24M 2,019,674 AEE01CC24M 2,134,001 AEE03A48M 1,749,638 AEE01B48M 1,866,230 AEE01C48M 1,953,706 AEE01H48M 1,809,937 AEE01BB48M 1,809,937 AEE01CC48M 2,031,988 Hours
Application Notes AEE15WM Series Page 33 Input ReflectedRipple Current Test Setup Input reflectedripple current is measured with a inductor Lin (4.7µH) and Cin (220uF, ESR < 1.0Ω at KHz) to simulate source impedance. Capacitor Cin, offsets possible battery impedance. Current ripple is measured at the input terminals of the module, measurement bandwidth is 0500KHz. To Oscilloscope +Vin +Out + + Lin Battery Cin Current Probe DC / DC Converter Vin Out Load Component Value Reference Lin 4.7µH Cin 220uF (ESR<1.0Ω at KHz) Aluminum Electrolytic Capacitor.
Output Ripple Reduction A good quality low ESR capacitor placed as close as practicable across the load will give the best ripple and noise performance. To reduce output ripple, it is recommended to use 4.7uF capacitors at the output. AEE15WM Series Page 34 + +Vin +Out DC Power Source Vin Single Output DC / DC Converter Out Cout Load + +Vin +Out DC Power Source Vin Dual Output DC / DC Converter Com. Out Cout Cout Load Load PeaktoPeak Output Noise Measurement Test Use a 4.7uF ceramic capacitor. Scope measurement should be made by using a BNC socket, measurement bandwidth is 020MHz. Position the load between 50mm and 75mm from the DC/DC Converter +Vin +Out Copper Strip Single Output DC / DC Converter Cout Scope Resistive Load Vin Out Copper Strip +Vin Dual Output DC / DC Converter Vin +Out Com. Out Copper Strip Cout Copper Strip Cout Copper Strip Scope Scope Resistive Load
Input Source Impedance AEE15WM Series Page 35 The power module should be connected to a low acimpedance input source. Highly inductive source impedances can affect the stability of the power module. In applications where power is supplied over long lines and output loading is high, it may be necessary to use a capacitor at the input to ensure startup. Capacitor mounted close to the power module helps ensure stability of the unit, it is recommended to use a good quality low Equivalent Series Resistance (ESR < 1.0Ω at KHz) capacitor of a 10uF for the 12V input modules and a 4.7uF for the 24V input modules and a 2.2uF for the 48V input modules. + +Vin +Out DC Power Source + Cin Vin DC / DC Converter Out Load Output Over Current Protection To provide hiccup mode protection in a fault (output overload) condition, the unit is equipped with internal current limiting circuitry and can endure overload for an unlimited duration. Output Over Voltage Protection The output overvoltage clamp consists of control circuitry, which is independent of the primary regulation loop, that monitors the voltage on the output terminals. The control loop of the clamp has a higher voltage set point than the primary loop. This provides a redundant voltage control that reduces the risk of output overvoltage. The OVP level can be found in Table 3. Thermal Considerations Many conditions affect the thermal performance of the power module, such as orientation, airflow over the module and board spacing. To avoid exceeding the maximum temperature rating of the components inside the power module, the case temperature must be kept below 95 O C. The derating curves are determined from measurements obtained in a test setup. Position of air velocity probe and thermocouple 15mm / 0.6in 50mm / 2in Air Flow DUT Maximum Capacitive Load The AEE15WM series has limitation of maximum connected capacitance at the output. The power module may be operated in current limiting mode during startup, affecting the rampup and the startup time. The maximum capacitance can be found in the Table 3.
Packaging Information AEE15WM Series Page 36 23.0 278.0 55.0 R MINMAX R MINMAX R MINMAX R MINMAX R MINMAX Soldering and Reflow Considerations Lead free wave solder profile for AEE15WM Series T1+T2 1st WAVW 2nd WAVW Preheat zone TIME(SEC) Zone Preheat zone Actual heating Reference Parameter Rise temp speed:3 O C/Sec max. Preheat temp : ~130 O C Peak temp: 250~260 O C Peak Time Peak time(t1+t2):4~6 sec Reference Solder: SnAgCu:SnCu:SnAg Hand Welding: Soldering iron:power 60W Welding Time: 2~4 sec Temp.: 380~400 O C
Record of Revision and Changes AEE15WM Series Page 37 Issue Date Description Originators 1.0 01.11.2017 First Issue X. Sun For more information: www.artesyn.com/power For support: productsupport.ep@artesyn.com