AEE00B48-M - Artesyn Embedded Technologies

Rev.02.13.15_#1.3

AEE10W-M Series

Page 1

Technical Reference Note

AEE10W-M Series

10 Watts

DC/DC Converter

Total Power: 10 Watts

Input Voltage: 9 to 18 Vdc

18 to 36 Vdc

36 to 75Vdc

# of Outputs: Single, dual

Special Features

•4200VAC reinforced Insulation

•Insulation rated for 300VAC

Working Voltage

•Medical Safety to UL/CSA/EN/IEC

60601-1 3rd Edition

• 2 MOOP rated

• Wide 2:1 Input Voltage Range

• Excellent Efficiency up to 82%

• Fully regulated Output Voltage

• Low Leakage Current

• Operating Temperature Range –40

OC to +85 OC (With derating)

• Input Filter meets EN 55022, class

• A and FCC, level A

• Overload Protection

• 2”x 1” Plastic Package

• 3 Years Product Warranty

Safety

cUL/UL60950-1, CSA C22.2 No.

60950-1-03

UL60601-1, CSA C22.2 No.601-1

IEC/EN 60950-1, IEC/EN 60601-1

3rd Edition, 2 MOOP

IEC60950-1 CB report, cUL/UL

60950-1 certificate

UL60601-1 UL certificate

Product Descriptions

The AEE10W-M series is the new range of high performance dc-dc converter

modules 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 AEE10W-M 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.

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

Page 2

Technical Reference Note

Artesyn Embedded Technologies

Model Numbers

Options

Model Input Voltage Output Voltage Maximum Load Efficiency

AEE01A12-M 9-18Vdc 5V 1.6A 76%

AEE00B12-M 9-18Vdc 12V 0.835A 80%

AEE00BB12-M 9-18Vdc ±12 V ±0.417 80%

AEE00CC12-M 9-18Vdc ±15 V ±0.333 81%

AEE02A24-M 18-36Vdc 5V 2A 77%

AEE00B24-M 18-36Vdc 12V 0.835A 81%

AEE00BB24-M 18-36Vdc ±12 V ±0.417 81%

AEE00CC24-M 18-36Vdc ±15 V ±0.333 82%

AEE02A48-M 36-75Vdc 5V 2A 77%

AEE00B48-M 36-75Vdc 12V 0.835A 81%

AEE00BB48-M 36-75Vdc ±12 V ±0.417 81%

AEE00CC48-M 36-75Vdc ±15 V ±0.333 82%

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

Page 3

Technical Reference Note

Artesyn Embedded Technologies

Table 1. Absolute Maximum Ratings:

Parameter Model Symbol Min Typ Max Unit

Input Surge Voltage

1 Sec.max

12V input Models

24V input Models

48V input Models

VIN,DC

-0.7

100

Vdc

Maximum Output Power All PO,max - - 10 W

Isolation Voltage

Input to output (60 seconds) All models 4200 - - Vac

Isolation Voltage

Input to output (1 second) All models 6000 - - Vac

Isolation Resistance All models 10 - - Gohm

Isolation Capacitance All models - 60 80 pF

Operating Ambient Temperature Range Natural Convection -40 +85 OC

Operating Case Temperature All TCASE - - +95 OC

Storage Temperature All TSTG -50 +125 OC

Humidity (non-condensing)

Operating

Non-operating

All

MTBF MIL-HDBK-

217F@25OC, Ground

Benign

1000000 - - Hours

Electrical Specifications

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.

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

Page 4

Technical Reference Note

Artesyn Embedded Technologies

Input Specifications

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 VIN,DC

Vdc

Start-Up Threshold

Voltage

12V input Models

24V Input Models

48V Input Models

All VIN,start

Vdc

Under Voltage Lockout

12V input Models

24V Input Models

48V Input Models

All VIN,under

8.5

Vdc

Input reflected ripple

current

12V input Models

24V Input Models

48V Input Models

0 to 500MHz,4.7uH

source impedance IIN,ripple

100

Input Current

AEE01A12-M

AEE00B12-M

AEE00BB12-M

AEE00CC12-M

AEE02A24-M

AEE00B24-M

AEE00BB24-M

AEE00CC24-M

AEE02A48-M

AEE00B48-M

AEE00BB48-M

AEE00CC48-M

VIN,DC=VIN,nom IIN,full load

877

1044

1042

1028

541

516

508

271

258

254

No Load Input Current

(VOOn, IO= 0A)

AEE01A12-M

AEE00B12-M

AEE00BB12-M

AEE00CC12-M

AEE02A24-M

AEE00B24-M

AEE00BB24-M

AEE00CC24-M

AEE02A48-M

AEE00B48-M

AEE00BB48-M

AEE00CC48-M

VIN,DC=VIN,nom IIN,no_load

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

Page 5

Technical Reference Note

Artesyn Embedded Technologies

Input Specifications

Table 2. Input Specifications con’t:

Parameter Condition Symbol Min Nom Max Unit

Efficiency @Max. Load

AEE01A12-M

AEE00B12-M

AEE00BB12-M

AEE00CC12-M

AEE02A24-M

AEE00B24-M

AEE00BB24-M

AEE00CC24-M

AEE02A48-M

AEE00B48-M

AEE00BB48-M

AEE00CC48-M

VIN,DC=VIN,nom

IO=IO,max

TA=25 OC

76%

80%

81%

77%

81%

82%

77%

81%

82%

Leakage current All Modules VIN,DC=240Vdc

F=60HZ leakage - - 10 uA

Short circuit input

power All Modules - - 3000 mW

Internal Power

Dissipation All Modules - - 4000 mW

Internal Filter Type All Internal LC Filter (for EN55022,Class A )

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

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Artesyn Embedded Technologies

Table 3. Output Specifications:

Parameter Condition Symbol Min Nom Max Unit

Output Voltage Set-

Point

AEE01A12-M

AEE00B12-M

AEE00BB12-M

AEE00CC12-M

AEE02A24-M

AEE00B24-M

AEE00BB24-M

AEE00CC24-M

AEE02A48-M

AEE00B48-M

AEE00BB48-M

AEE00CC48-M

VIN,DC=VIN,nom

IO=IO,max

TA=25 OC

12V

±12 V

±15 V

12V

±12 V

±15 V

12V

±12 V

±15 V

Vdc

Output Current

AEE01A12-M

AEE00B12-M

AEE00BB12-M

AEE00CC12-M

AEE02A24-M

AEE00B24-M

AEE00BB24-M

AEE00CC24-M

AEE02A48-M

AEE00B48-M

AEE00BB48-M

AEE00CC48-M

Convection cooling IO

1.6A

0.835A

±0.417

±0.333

0.835A

±0.417

±0.333

0.835A

±0.417

±0.333

VOLoad Capacitance

AEE01A12-M

AEE00B12-M

AEE00BB12-M

AEE00CC12-M

AEE02A24-M

AEE00B24-M

AEE00BB24-M

AEE00CC24-M

AEE02A48-M

AEE00B48-M

AEE00BB48-M

AEE00CC48-M

All

1000

470

220

1000

470

220

1000

470

220

Output Specifications

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

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Technical Reference Note

Artesyn Embedded Technologies

Table 3. Output Specifications con’t:

Parameter Condition Symbol Min Nom Max Unit

VOLoad Capacitance

AEE01A12-M

AEE00B12-M

AEE00BB12-M

AEE00CC12-M

AEE02A24-M

AEE00B24-M

AEE00BB24-M

AEE00CC24-M

AEE02A48-M

AEE00B48-M

AEE00BB48-M

AEE00CC48-M

All

1000

470

220

1000

470

220

1000

470

220

Line Regulation VIN,DC=VIN,min to VIN,max ±%VO- 0.3 0.5 %

Load Regulation IO=IO,min to IO,max ±%VO- 0.5 1.2 %

Switching Frequency All fSW 120 150 180 KHz

VODynamic Response

Peak Deviation

Settling Time

25% load change ±%VO

250

uSec

Temperature Coefficient All %/OC - 0.02 0.05 %

Output Over Current Protection1All %IO,max 120 150 - %

Output Short Circuit Protection All Hiccup Automatic Recovery

Note 1 - Hiccup Automatic Recovery

Output Specifications

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

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AEE01A12-M Performance Curves

Figure 4: AEE01A12-M Transient Response

Vin = 12Vdc Load: Io = 100% to 75% load change

Ch 1: Vo

Figure 1: AEE01A12-M Efficiency Versus Output Current Curve

Vin = 9 to 18Vdc Load: Io = 0 to 1.6A

Figure 2: AEE01A12-M Efficiency Versus Input Voltage Curve

Vin = 9 to 18Vdc Load: Io = 1.6A

Figure 3 AEE01A12-M Ripple and Noise Measurement

Vin = 12Vdc Load: Io = 1.6A

Ch 1: Vo

Figure 5: AEE01A12-M Output Voltage Startup Characteristic by Vin

Vin = 12Vdc Load: Io = 1.6A

Ch1: Vo Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

Efficiency(%)

12V

18V

9 12 18

Input Voltage(V)

E ffic ienc y(% )

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

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Technical Reference Note

Artesyn Embedded Technologies

AEE01A12-M Performance Curves

Note - All test conditions are at 25 OC

Figure 6: AEE01A12-M Derating Curves (without heatsink)

Vin = 12Vdc Load: Io = 0 to 1.6A

Figure 7: AEE01A12-M Conduction Emission of EN550122 Class A

Vin = 12Vdc Load: Io = 1.6A

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 1108040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

Page 10

Technical Reference Note

Artesyn Embedded Technologies

AEE00B12-M Performance Curves

Figure 11: AEE00B12-M Transient Response

Vin = 12Vdc Load: Io = 100% to 75% load change

Ch 1: Vo

Figure 8: AEE00B12-M Efficiency Versus Output Current Curve

Vin = 9 to 18Vdc Load: Io = 0 to 0.835A

Figure 9: AEE00B12-M Efficiency Versus Input Voltage Curve

Vin = 9 to 18Vdc Load: Io = 0.835A

Figure 10: AEE00B12-M Ripple and Noise Measurement

Vin = 12Vdc Load: Io = 0.835A

Ch 1: Vo

Figure 12: AEE00B12-M Output Voltage Startup Characteristic by Vin

Vin = 12Vdc Load: Io = 0.835A

Ch1: Vo Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

Efficiency(%)

12V

18V

9 12 18

Input Voltage(V)

Efficiency(%)

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

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Technical Reference Note

Artesyn Embedded Technologies

AEE00B12-M Performance Curves

Note - All test conditions are at 25 OC

Figure 13: AEE00B12-M Derating Curves (without heatsink)

Vin = 12Vdc Load: Io = 0 to 0.835A

Figure 14: AEE00B12-M Conduction Emission of EN550122 Class A

Vin = 12Vdc Load: Io = 0.835A

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 110

8040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

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Technical Reference Note

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AEE00BB12-M Performance Curves

Figure 18: AEE00BB12-M Transient Response

Vin = 12Vdc Load: Io = 100% to 75% load change

Ch 1: Vo1 Ch2: Vo2

Figure 15: AEE00BB12-M Efficiency Versus Output Current Curve

Vin = 9 to 18Vdc Load: Io = 0 to ±

±±

±0.417A

Figure 16: AEE00BB12-M Efficiency Versus Input Voltage Curve

Vin = 9 to 18Vdc Load: Io = ±

±±

±0.417

Figure 17: AEE00BB12-M Ripple and Noise Measurement

Vin = 12Vdc Load: Io = ±

±±

±0.417

Ch 1: Vo1 Ch2: Vo2

Figure 19: AEE00BB12-M Output Voltage Startup Characteristic by Vin

Vin = 12Vdc Load: Io = ±

±±

±0.417A

Ch1: Vo1 Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

Efficiency(%)

12V

18V

9 12 18

Input Voltage(V)

Efficiency(%)

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

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Artesyn Embedded Technologies

AEE00BB12-M Performance Curves

Note - All test conditions are at 25 OC

Figure 20: AEE00BB12-M Derating Curves (without heatsink)

Vin = 12Vdc Load: Io = 0 to ±0.417

Figure 21: AEE00BB12-M Conduction Emission of EN550122 Class A

Vin = 12Vdc Load: Io = 1 ±0.417

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 110

8040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

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AEE00CC12-M Performance Curves

Figure 25: AEE00CC12-M Transient Response

Vin = 12Vdc Load: Io = 100% to 75% load change

Ch 1: Vo1 Ch2: Vo2

Figure 22: AEE00CC12-M Efficiency Versus Output Current Curve

Vin = 9 to 18Vdc Load: Io = 0 to ±

±±

±0.333

Figure 23: AEE00CC12-M Efficiency Versus Input Voltage Curve

Vin = 9 to 18Vdc Load: Io = ±

±±

±0.333

Figure 24: AEE00CC12-M Ripple and Noise Measurement

Vin = 12Vdc Load: Io = ±

±±

±0.333

Ch 1: Vo1 Ch2: Vo2

Figure 26: AEE00CC12-M Output Voltage Startup Characteristic by Vin

Vin = 12Vdc Load: Io = ±

±±

±0.333

Ch1: Vo1 Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

Efficiency(%)

12V

18V

9 12 18

Input Voltage(V)

Efficiency(%)

Technical Reference Note

Rev.02.13.15_#1.3

AEE10W-M Series

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AEE00CC12-M Performance Curves

Note - All test conditions are at 25 OC

Figure 27: AEE00CC12-M Derating Curves (without heatsink)

Vin = 12Vdc Load: Io = 0 to ±0.333

Figure 28: AEE00CC12-M Conduction Emission of EN550122 Class A

Vin = 12Vdc Load: Io = ±0.333

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 1108040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

Technical Reference Note

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AEE02A24-M Performance Curves

Figure 32: AEE02A24-M Transient Response

Vin = 24Vdc Load: Io = 100% to 75% load change

Ch 1: Vo

Figure 29: AEE02A24-M Efficiency Versus Output Current Curve

Vin = 18 to 36Vdc Load: Io = 0 to 2A

Figure 30: AEE02A24-M Efficiency Versus Input Voltage Curve

Vin = 18 to 36Vdc Load: Io = 2A

Figure 31: AEE02A24-M Ripple and Noise Measurement

Vin = 24Vdc Load: Io = 2A

Ch 1: Vo

Figure 33: AEE02A24-M Output Voltage Startup Characteristic by Vin

Vin = 24Vdc Load: Io = 2A

Ch1: Vo Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

E f fic ienc y (% )

18V

24V

36V

18 24 36

Input Voltage(V)

Efficiency(%)

Technical Reference Note

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AEE02A24-M Performance Curves

Note - All test conditions are at 25 OC

Figure 34: AEE02A24-M Derating Curves (without heatsink)

Vin = 24Vdc Load: Io = 0 to 2A

Figure 35: AEE02A24-M Conduction Emission of EN550122 Class A

Vin = 24Vdc Load: Io = 2A

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 1108040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

Technical Reference Note

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AEE00B24-M Performance Curves

Figure 39: AEE00B24-M Transient Response

Vin = 24Vdc Load: Io = 100% to 75% load change

Ch 1: Vo

Figure 36: AEE00B24-M Efficiency Versus Output Current Curve

Vin = 18 to 36Vdc Load: Io = 0 to 0.835A

Figure 37: AEE00B24-M Efficiency Versus Input Voltage Curve

Vin = 18 to 36Vdc Load: Io = 0.835A

Figure 38: AEE00B24-M Ripple and Noise Measurement

Vin = 24Vdc Load: Io = 0.835A

Ch 1: Vo

Figure 40: AEE00B24-M Output Voltage Startup Characteristic by Vin

Vin = 24Vdc Load: Io = 0.835A

Ch1: Vo Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

Efficiency(%)

18V

24V

36V

18 24 36

Input Voltage(V)

Efficiency(%)

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AEE00B24-M Performance Curves

Note - All test conditions are at 25 OC

Figure 41: AEE00B24-M Derating Curves (without heatsink)

Vin = 24Vdc Load: Io = 0 to 0.835A

Figure 42: AEE00B24-M Conduction Emission of EN550122 Class A

Vin = 24Vdc Load: Io = 0.835A

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 110

8040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

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AEE00BB24-M Performance Curves

Figure 46: AEE00BB24-M Transient Response

Vin = 24Vdc Load: Io = 100% to 75% load change

Ch 1: Vo1 Ch2: Vo2

Figure 43: AEE00BB24-M Efficiency Versus Output Current Curve

Vin = 18 to 36Vdc Load: Io = 0 to ±

±±

±0.417A

Figure 44: AEE00BB24-M Efficiency Versus Input Voltage Curve

Vin = 18 to 36Vdc Load: Io = ±

±±

±0.417

Figure 45: AEE00BB24-M Ripple and Noise Measurement

Vin = 24Vdc Load: Io = ±

±±

±0.417

Ch 1: Vo1 Ch2: Vo2

Figure 47: AEE00BB24-M Output Voltage Startup Characteristic by Vin

Vin = 24Vdc Load: Io = ±

±±

±0.417A

Ch1: Vo1 Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

E ffic ie nc y (% )

18V

24V

36V

18 24 36

Input Voltage(V)

Efficiency(%)

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AEE00BB24-M Performance Curves

Note - All test conditions are at 25 OC

Figure 48: AEE00BB24-M Derating Curves (without heatsink)

Vin = 24Vdc Load: Io = 0 to ±0.417

Figure 49: AEE00BB24-M Conduction Emission of EN550122 Class A

Vin = 24Vdc Load: Io = 1 ±0.417

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 1108040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

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AEE00CC24-M Performance Curves

Figure 53: AEE00CC24-M Transient Response

Vin = 12Vdc Load: Io = 100% to 75% load change

Ch 1: Vo1 Ch2: Vo2

Figure 50: AEE00CC24-M Efficiency Versus Output Current Curve

Vin = 18 to 36Vdc Load: Io = 0 to ±

±±

±0.333

Figure 51: AEE00CC24-M Efficiency Versus Input Voltage Curve

Vin = 18 to 36Vdc Load: Io = ±

±±

±0.333

Figure 52: AEE00CC24-M Ripple and Noise Measurement

Vin = 12Vdc Load: Io = ±

±±

±0.333

Ch 1: Vo1 Ch2: Vo2

Figure 54: AEE00CC24-M Output Voltage Startup Characteristic by Vin

Vin = 12Vdc Load: Io = ±

±±

±0.333

Ch1: Vo1 Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

Efficiency(%)

18V

24V

36V

18 24 36

Input Voltage(V)

Efficiency(%)

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AEE00CC24-M Performance Curves

Note - All test conditions are at 25 OC

Figure 55: AEE00CC24-M Derating Curves (without heatsink)

Vin = 24Vdc Load: Io = 0 to ±0.333

Figure 56: AEE00CC24-M Conduction Emission of EN550122 Class A

Vin = 24Vdc Load: Io = ±0.333

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 1108040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

Technical Reference Note

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AEE02A48-M Performance Curves

Figure 60: AEE02A48-M Transient Response

Vin = 48Vdc Load: Io = 100% to 75% load change

Ch 1: Vo

Figure 57: AEE02A48-M Efficiency Versus Output Current Curve

Vin = 36 to 75Vdc Load: Io = 0 to 2A

Figure 58: AEE02A48-M Efficiency Versus Input Voltage Curve

Vin = 36 to 75Vdc Load: Io = 2A

Figure 59: AEE02A48-M Ripple and Noise Measurement

Vin = 48Vdc Load: Io = 2A

Ch 1: Vo

Figure 61: AEE02A48-M Output Voltage Startup Characteristic by Vin

Vin = 48Vdc Load: Io = 2A

Ch1: Vo Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

E ffic ienc y (% )

36V

48V

75V

36 49 75

Input Voltage(V)

Efficiency(%)

Technical Reference Note

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AEE02A48-M Performance Curves

Note - All test conditions are at 25 OC

Figure 62: AEE02A48-M Derating Curves (without heatsink)

Vin = 48Vdc Load: Io = 0 to 2A

Figure 63: AEE02A48-M Conduction Emission of EN550122 Class A

Vin = 48Vdc Load: Io = 2A

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 110

8040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

Technical Reference Note

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AEE00B48-M Performance Curves

Figure 67: AEE00B48-M Transient Response

Vin = 48Vdc Load: Io = 100% to 75% load change

Ch 1: Vo

Figure 64: AEE00B48-M Efficiency Versus Output Current Curve

Vin = 36 to 75Vdc Load: Io = 0 to 0.835A

Figure 65: AEE00B48-M Efficiency Versus Input Voltage Curve

Vin = 36 to 75Vdc Load: Io = 0.835A

Figure 66: AEE00B24-M Ripple and Noise Measurement

Vin = 48Vdc Load: Io = 0.835A

Ch 1: Vo

Figure 68: AEE00B48-M Output Voltage Startup Characteristic by Vin

Vin = 48Vdc Load: Io = 0.835A

Ch1: Vo Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

Efficiency(%)

36V

48V

75V

36 49 75

Input Voltage(V)

Efficiency(%)

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AEE00B48-M Performance Curves

Note - All test conditions are at 25 OC

Figure 69: AEE00B48-M Derating Curves (without heatsink)

Vin = 48Vdc Load: Io = 0 to 0.835A

Figure 70: AEE00B48-M Conduction Emission of EN550122 Class A

Vin = 48Vdc Load: Io = 0.835A

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 110

8040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

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AEE00BB48-M Performance Curves

Figure 74: AEE00BB48-M Transient Response

Vin = 48Vdc Load: Io = 100% to 75% load change

Ch 1: Vo1 Ch2: Vo2

Figure 71: AEE00BB48-M Efficiency Versus Output Current Curve

Vin = 36 to 75Vdc Load: Io = 0 to ±

±±

±0.417A

Figure 72: AEE00BB48-M Efficiency Versus Input Voltage Curve

Vin = 36 to 75Vdc Load: Io = ±

±±

±0.417

Figure 73: AEE00BB48-M Ripple and Noise Measurement

Vin = 48Vdc Load: Io = ±

±±

±0.417

Ch 1: Vo1 Ch2: Vo2

Figure 75: AEE00BB48-M Output Voltage Startup Characteristic by Vin

Vin = 48Vdc Load: Io = ±

±±

±0.417A

Ch1: Vo1 Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

Efficiency(%)

36V

48V

75V

36 49 75

Input Voltage(V)

Efficiency(%)

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AEE00BB48-M Performance Curves

Note - All test conditions are at 25 OC

Figure 76: AEE00BB48-M Derating Curves (without heatsink)

Vin = 48Vdc Load: Io = 0 to ±0.417

Figure 77: AEE00BB48-M Conduction Emission of EN550122 Class A

Vin = 48Vdc Load: Io = 1 ±0.417

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 1108040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

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AEE00CC48-M Performance Curves

Figure 81: AEE00CC48-M Transient Response

Vin = 48Vdc Load: Io = 100% to 75% load change

Ch 1: Vo1 Ch2: Vo2

Figure 78: AEE00CC48-M Efficiency Versus Output Current Curve

Vin = 36 to 75Vdc Load: Io = 0 to ±

±±

±0.333

Figure 79: AEE00CC48-M Efficiency Versus Input Voltage Curve

Vin = 36 to 75Vdc Load: Io = ±

±±

±0.333

Figure 80: AEE00CC48-M Ripple and Noise Measurement

Vin = 48Vdc Load: Io = ±

±±

±0.333

Ch 1: Vo1 Ch2: Vo2

Figure 82: AEE00CC48-M Output Voltage Startup Characteristic by Vin

Vin = 48Vdc Load: Io = ±

±±

±0.333

Ch1: Vo1 Ch2: Vin

10 20 30 40 50 60 70 80 90 100

% of Full Load

Efficiency(%)

36V

48V

75V

36 49 75

Input Voltage(V)

Efficiency(%)

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AEE00CC48-M Performance Curves

Note - All test conditions are at 25 OC

Figure 83: AEE00CC48-M Derating Curves (without heatsink)

Vin = 48Vdc Load: Io = 0 to ±0.333

Figure 84: AEE00CC48-M Conduction Emission of EN550122 Class A

Vin = 48Vdc Load: Io = ±0.333

Ambient Temperature

Output Power (%)

100

-40 0 20 60 100 1108040

400LFM

200LFM

100LFM

Natural

Convection

20LFM

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Mechanical Specifications

Mechanical Outlines

Note:

1.All dimensions in mm (inches)

2.Tolerance: X.X±0.25 (X.XX±0.01)

X.XX±0.13 ( X.XXX±0.005)

3.Pin diameter 1.0 ±0.05 (0.04±0.002)

Pin Connections

Single output

Pin 1 – +Vin

Pin 2 – -Vin

Pin 3 – +Vout

Pin 4 – No Pin

Pin 5 – -Vout

Dual Output

Pin 1 – +Vin

Pin 2 – -Vin

Pin 3 – +Vout

Pin 4 – Common

Pin 5 – -Vout

10.16

25.4 [1.00]

[0.40]

10.16

[0.40]

2.54

[0.10]

5.08

[0.20]

Bottom View

45.72 [1.80]

50.8 [2.00]

1.00 [0.04]

5 4

5.08

[0.20]

12.0

[0.47]

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Recommended Pad Layout

Top View

45.72 [1.80]

50.8 [2.0]

[0.20]

5.08

10.16

[0.40]

10.16

[0.40]

5X 2.0 0.1(PAD)[5X 0.08 0.004 ]

25.4 [1.00]

5X 1.3 0.1(HOLE)[5X 0.05 0.004]

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Environmental Specifications

EMC Immunity

AEE10W-M series power supply is designed to meet the following EMC immunity specifications.

Table 4. EMC Specifications:

Parameter Standards & Level Performance

EMI EN55022 Class A

ESD EN61000-4-2 air ±8KV , Contact ±6KV Perf. Criteria A

Radiated immunity EN61000-4-3 10V/m Perf. Criteria A

Fast transient1EN61000-4-4 ±2KV Perf. Criteria A

Surge1EN61000-4-5 ±1KV Perf. Criteria A

Conducted immunity EN61000-4-6 10Vrms Perf. Criteria A

Note 1 - AEE10W-M series can meet EN61000-4-4 & EN61000-4-5 by adding a capacitor across the input pins. Suggested capacitor:

CHEMI-CON KY 220uF/100V

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Safety Certifications

The AEE10W-M 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 AEE10W-M series power supply system

Document Description

cUL/UL 60950-1 (CSA certificate) US and Canada Requirements

IEC/EN 60950-1 (CB-scheme) European Requirements (All CENELEC Countries)

UL60601-1 US Medical Requirements

IEC/EN 60950-1, IEC/EN 60601-1

3rd Edition, 2 MOOP International and European Medical Requirements

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Operating Temperature

Table 6. Operating Temperature:

Parameter Model / Condition Min Max Unit

Operating Temperature Range

(Natural Convection1, See Derating) All -40 +85 OC

Operating Case Temperature All -+95 OC

Thermal Protection Shutdown

Temperature -110 OC

Storage Temperature Range -50 +125 OC

Humidity (non condensing) -95 %

Altitude -4000 m

Cooling Free-Air convection

Lead Temperature (1.5mm from case for

10Sec.) - 260 OC

Note1 - The “natural convection” is about 20LFM but is not equal to still air (0 LFM).

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MTBF and Reliability

The MTBF of AEE10W-M series of DC/DC converters has been calculated using MIL-HDBK 217F NOTICE2, Operating

Temperature 25 OC, Ground Benign.

Model MTBF Unit

AEE01A12-M 1040000

Hours

AEE00B12-M 1320000

AEE00BB12-M 1140000

AEE00CC12-M 1290000

AEE02A24-M 1000000

AEE00B24-M 1310000

AEE00BB24-M 1380000

AEE00CC24-M 1530000

AEE02A48-M 1100000

AEE00B48-M 1080000

AEE00BB48-M 1050000

AEE00CC48-M 1380000

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Application Notes

Input Reflected-Ripple Current Test Setup

Input reflected-ripple current is measured with a inductor Lin (4.7µH) and Cin (220uF, ESR < 1.0Ω at 100 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 0-500 KHz.

Component Value Reference

Lin 4.7µH -

Cin 220uF (ESR<1.0Ω at 100KHz) Aluminum Electrolytic Capacitor

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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 3.3uF capacitors at the output.

Peak-to-Peak Output Noise Measurement Test

Use a 0.47uF ceramic capacitor. Scope measurement should be made by using a BNC socket, measurement bandwidth

is 0-20MHz. Position the load between 50 mm and 75 mm from the DC/DC Converter

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Input Source Impedance

The power module should be connected to a low ac-impedance 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 100 KHz) capacitor of a 10uFfor the 24V and 48V devices.

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.

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 OC. The derating curves are determined from measurements obtained in a test setup.

Maximum Capacitive Load

The AEE10W-M series has limitation of maximum connected capacitance at the output. The power module may be

operated in current limiting mode during start-up, affecting the ramp-up and the startup time. The maximum capacitance

can be found in the Table 3.

+Out

-Out

+Vin

-Vin

DC / DC

Converter Load

DC Power

Source

Cin

DUT

Position of air velocity

probe and thermocouple 50mm / 2in Air Flow

15mm / 0.6in

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Packaging Information

Soldering and Reflow Considerations

Lead free wave solder profile for AEE10W -M Series

Reference Solder: Sn-Ag-Cu：Sn-Cu：Sn-Ag

Hand Welding: Soldering iron：Power 10W

Welding Time: 2~4 sec

Temp.: 380~400 OC

Zone Reference Parameter

Preheat zone

Rise temp speed：3OC/sec max.

Preheat temp : 100~130OC

Actual heating Peak temp: 250~260OC Peak Time

Peak time(T1+T2)：4~6 sec

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For more information: www.artesyn.com/power

For support: productsupport.ep@artesyn.com