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HAE200W_14 Datasheet, PDF (3/4 Pages) Power Mate Technology Co., LTD – HALF-BRICK DC-DC CONVERTER
HAE200W
ENVIRONMENTAL SPECIFICATIONS
Parameter
Conditions
Operating case temperature
Base-plate
Over temperature protection
Storage temperature range
Terminal block type
Others
Thermal impedance (3)
Vertical direction by natural convection (20LFM)
Module without assembly option
Only mount on the iron base-plate
Heat-sink type with 0.24" Height
Heat-sink type with 0.45" Height
Thermal shock
Shock
Vibration
Relative humidity
Min.
-40
-40
-55
Typ.
+120
Max.
+115
+105
+125
U℃℃℃nit
6.1
2.8
℃/W
5.1
4.6
MIL-STD-810F
EN61373, MIL-STD-810F
EN61373, MIL-STD-810F
5% to 95% RH
EMC SPECIFICATIONS
Parameter
EMI (4)
ESD
Radiated immunity
Fast transient (5)
Surge (5)
Conducted immunity
EN55011, EN55022
EN61000-4-2
EN61000-4-3
EN61000-4-4
EN61000-4-5
EN61000-4-6
Conditions
Air ± 8kV and Contact ± 6kV
20V/m
± 2kV
EN55024 ±2kV and EN50155 ±2kV
10Vr.m.s
Level
Class A
Class B
Perf. Criteria A
Perf. Criteria A
Perf. Criteria A
Perf. Criteria A
Perf. Criteria A
Note:
1. Input source impedance: The power modules will operate as specifications without external components, assuming that the source voltage has a
very low impedance and reasonable input voltage regulation. Highly inductive source impedances can affect the stability of the power module.
Since real-world voltage source has finite impedance, performance can be improved by adding external filter capacitor.
The HAE200-24S W and HAE200-48S W recommended Nippon Chemi-con KY series, 100µF/100V.
The HAE200-110S W recommended Ruby-con BXF series, 68µF/200V.
2. (1)Multiple HAE200W series module can be synchronized together simply by connecting the Sync pins together. Care should be taken to ensure
the ground potential differences between modules are minimized.
(2)In this configuration all of the modules will be synchronized to the highest frequency module.
(3)Up to three modules can be synchronized using this technique.
(4)More relevant information in datasheet.
3. (1)Thermal test condition with vertical direction by natural convection (20LFM).
(2)The iron base-plate dimension is 19” X 3.5” X 0.063” (The height is EIA standard 2U).
(3) The heat-sink is optional and P/N: 7G-0021A-F , 7G-0022A-F , 7G-0023A-F , 7G-0024A-F. Please refer to heat-sink selection guide.
4. The HAE200W series standard module meets EN55011, EN55022 Class A and Class B with external components.
5. An external input filter capacitor is required if the module has to meet EN61000-4-4, EN61000-4-5.
The HAE200-24S W and HAE200-48S W recommended 2 pcs of aluminum electrolytic capacitor (Nippon Chemi-con KY series,
220µF/100V) to connect in parallel.
: The HAE200-110S W recommended 3 pcs of aluminum electrolytic capacitor (Ruby-con BXF series, 100µF/250V) to connect in parallel.
6. CASE GROUNDING Connecting four screw bolts to shield plane will help to reduce the EMI.
7. For further information, please contact with P-DUKE.
CAUTION: This power module is not internally fused. An input line fuse must always be used.
CHARACTERISTIC CURVE
120
100
80
DC/DC module only
100LFM
60
200LFM
300LFM
400LFM
40
500LFM
Mount on 2U iron base-plate
(dimension 19” X 3.5” X 0.063”)
20
Natural convection (20LFM)
Terminal block
Natural convection (20LFM)
0
-40
-20
℃ 0
20 40 60 80 100 120
AMBIENT TEMPERATURE,TA( )
HAE200-48S05W Derating Curve (Note 3)
120
100
80
60
40
Natural convection (20LFM)
100LFM
200LFM
20
300LFM
400LFM
500LFM
0
-40
-20
℃ 0
20 40 60 80 100 120
AMBIENT TEMPERATURE,TA( )
HAE200-48S05W Derating Curve (Note 3)
With 0.24” Height Heat-sink
120
100
80
60
40
Natural convection (20LFM)
100LFM
200LFM
20
300LFM
400LFM
500LFM
0
-40
-20
℃ 0
20 40 60 80 100 120
AMBIENT TEMPERATURE,TA( )
HAE200-48S05W Derating Curve (Note 3)
With 0.45” Height Heat-sink
96
90
84
78
72
66
Iout= 100% F.L
Iout= 50% F.L
Iout= 25% F.L
60
16.5 24 30 36 42 48 54 60 66 72 75
INPUT VOLTAGE(V)
HAE200-48S05W Efficiency vs. Input Voltage
3
96
90
84
78
72
Vin= 16.5V
66
Vin= 24V
Vin= 48V
Vin= 75V
60
10 20 30 40 50 60 70 80 90 100
% of FULL LOAD
HAE200-48S05W Efficiency vs. Output Load
www.PDUKE.com
2014/4/30