12H1301-7RD7 [BEL]
DC-DC Regulated Power Supply Module, 1 Output, METAL, CASE H02, MODULE;型号: | 12H1301-7RD7 |
厂家: | BEL FUSE INC. |
描述: | DC-DC Regulated Power Supply Module, 1 Output, METAL, CASE H02, MODULE |
文件: | 总19页 (文件大小:356K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
H Series Data Sheet
50 Watt DC-DC Cassette Converters
Features
Wide input voltage ranges up to 60 VDC
1, 2, or 3 outputs up to 48 VDC
Class I equipment
• Wide input voltage range suitable for battery operation
• Efficient input filter and built-in surge and transient
suppression circuitry
• Outputs individually isolated
• Outputs fully protected against overload
111
4.37"
3U
Safety according to IEC/EN 60950
168
6.6"
39
1.54"
8TE
Description
safety agencies TÜV and UL (USA and Canada).
The H series of DC-DC converters represents a broad and
flexible range of cassette power supplies for use in
advanced electronic systems. Features include high
efficiency, reliability, and reasonable output voltage noise.
The case design allows operation at nominal load up to
50 °C in a free air ambient temperature. If forced cooling is
provided, the ambient temperature may exceed 50 °C, but
the case temperature should remain below 80 °C under all
conditions.
The converter inputs are protected against surges and
transients occuring at the source lines. Input over- and
undervoltage cut-out circuitry disables the outputs if the
input voltage is outside the specified range.
A temperature sensor generates an inhibit signal which
disables the outputs if the case temperature TC exceeds the
limit. The outputs are automatically re-enabled when the
temperature drops below the limit.
All outputs are open- and short-circuit proof and are
protected against overvoltages by means of built-in
suppressor diodes. The outputs can be inhibited by a logic
signal applied to the connector pin 2 (i). If the inhibit
function is not used, pin 2 should be connected to pin 23 to
enable the outputs.
Various options are available to adapt the converters to
individual applications.
The converters may either be plugged into 19-inch rack
systems according to DIN 41494, or be chassis mounted.
LED indicators display the status of the converter and allow
visual monitoring of the system at any time.
Full input-to-output, input-to-case, output-to-case, and
output-to-output isolation is provided. The converters are
designed and built according to the international safety
standard IEC/EN 60950 and have been approved by the
Table of Contents
Page
Page
Description ....................................................................... 1
Model Selection ............................................................... 2
Part Number Description and Product Marking ............... 2
Functional Description ..................................................... 3
Electrical Input Data ......................................................... 4
Electrical Output Data ...................................................... 5
Auxiliary Functions ........................................................... 8
Electromagnetic Compatibility (EMC) ............................ 10
Mechanical Data ............................................................ 11
Immunity to Environmental Conditions........................... 12
Safety and Installation Instructions ................................ 12
Description of Options.................................................... 15
Accessories.................................................................... 19
REV. MAR 27, 2006
Page 1 of 19
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H Series Data Sheet
50 Watt DC-DC Cassette Converters
Model Selection
Table 1: Model types
Output 1
Vo nom Io nom Vo nom Io nom Vo nom Io nom
[VDC] [A] [VDC] [A] [VDC] [A]
Output 2
Output 3
Input Voltage Range and Efficiency 1
ηmin Vi min to Vi max ηmin Vi min to Vi max
[%] 14 to 30 VDC 2 [%] 28 to 60VDC 2 [%]
Option
Vi min to V max
8 to 15 VDC 2
ηmin
5.1
8.0
4.0
3.4
2.0
1.0
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
12H1001-2R
12H1301-2R
12H1501-2R
12H1601-2R
12H1901-2R2
73
79
80
81
83
24H1001-2R
24H1301-2R
24H1501-2R
24H1601-2R
24H1901-2R2
75
82
82
83
85
48H1001-2R
48H1301-2R
48H1501-2R
48H1601-2R
48H1901-2R2
76
82
83
85
86
V2, V3
D1 to D8
-7
12.0
15.0
24.0
48.0
12.0
15.0
2.0
1.7
12.0
15.0
2.0
1.7
-
-
-
-
12H2320-2
12H2540-2
79
80
24H2320-2
24H2540-2
80
81
48H2320-2
48H2540-2
82
83
5.1
5.1
5.0
5.0
12.0
15.0
0.7
0.6
12.0
15.0
0.7
0.6
12H3020-2
12H3040-2
77
77
24H3020-2
24H3040-2
78
79
48H3020-2
48H3040-2
79
80
1 Efficiency measured at Vi nom and Io nom
2 Input voltage range 12H1901-2R: 9 to 15 VDC, 24H1901-2R: 18 to 30 VDC, 48H1901-2R: 36 to 60 VDC
Model numbers highlighted in yellow or shaded are not recommended for new designs.
Part Number Description and Product Marking
Type Key
48 H 2 5 40 -2 R D V
Input voltage range Vi:
8 to 15 VDC ............. 12
14 to 30 VDC ............. 24
28 to 60 VDC ............. 48
Series ...............................................................................H
Number of outputs .................................................... 1 to 3
Output 1, Vo1 nom
:
5.1 V ............... 0
12 V ............... 3
15 V ............... 5
24 V ............... 6
48 V ............... 9
Single output modules ................................................... 01
Output 2 and 3, Vo2 nom, Vo3 nom
:
12 V ............. 20
15 V ............. 40
Options and features:
Ambient temperature range TA –10 to 50 °C .................. -2
Extended temperature range TA –25 to 71 °C................. -7
Output voltage control input (single output modules only)R
Save data signal (D1 to D8, to be specified)....................D 1
ACFAIL signal (V2, V3, to be specified)........................... V 1
1 Option D excludes option V and vice versa
Example:
48H1501-2RD3: DC-DC converter, input voltage range 28 to 60 V, providing output with 15 V/3.4 A;
equipped with an output voltage control input and undervoltage monitoring.
REV. MAR 27, 2006
Page 2 of 19
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H Series Data Sheet
50 Watt DC-DC Cassette Converters
Functional Description
transistor.This signal is fed back via a coupling transformer.
The input voltage is fed via an input filter to the input
capacitor.This capacitor sources a single-transistor forward
converter. Each output is powered by a separate secondary
winding of the main transformer. The resultant voltages are
rectified and their ripples smoothed by a power choke. The
control logic senses the main output voltage Vo1 and
generates, with respect to the maximum admissible output
currents, the control signal for the primary switching
The auxiliary outputs Vo2 and Vo3 are unregulated. Each
auxiliary output's current is sensed and transferred to the
main control circuit using a current transformer. If one of the
outputs is driven into current limit, the other outputs will
reduce their output voltages as well because all output
currents are controlled by the same control circuit.
03067
2
i
5
D/V
1
Main control circuit
14
17
R
G
1
20
23
Y
29
Vi+
CMKT
14
17
Current
limitation
output 2
CMKT
8
32
Vi–
Current
limitation
output 3
Y
11
26
Y
Y
Y
1 Single output modules H1000 (R input)
Fig. 1
DC-DC converter block diagram
REV. MAR 27, 2006
Page 3 of 19
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H Series Data Sheet
50 Watt DC-DC Cassette Converters
Electrical Input Data
General conditions:
– TA = 25 °C, unless TC is specified.
– Connector pins 2 and 23 interconnected, R input not connected.
Table 2: Input data
Input
12H
24H
48H
Characteristics
Conditions
min
8
typ
max
15
min
14
typ
max
30
min
28
typ
max
60
Unit
Vi
Operating input voltage Io = 0 to Io nom
C min to TC max
VDC
T
..H1901-2R
Vi nom Nominal input voltage
9
15
18
30
36
60
12
24
48
1
Ii
Input current
Vi nom, Io nom
5.0
2.5
1.3
A
Pi 0
No-load input power:
Single output
Vi nom
Io1,2,3 = 0
1
4
4
1.5
6
6
1
4
4
1.5
6
6
1
4
4
1.5
6
6
W
Double output
Triple output
Pi inh Idle input power
inhibit mode
2
2
2
3
Iinr p Peak inrush current
Vi = Vi max
RS = 0 Ω 2
TC = 25°C
380
380
350
A
tinr r
Rise time
60
50
75
20
40
μs
tinr h Time to half value
110
Ri
Ci
Input resistance
TC = 25 °C
40
2200
0
80
750
0
175
190
0
mΩ
μF
Input capacitance
3300
20
1200
40
300
80
Ui abs Input voltage limits
without any damage
VDC
1 With multiple output modules, the same condition for each output applies.
2 RS = source resistance
3 Iinr p = Vi/(Rs + Ri)
Input Under-/Overvoltage Lockout
Input Fuse
The converters do not incorporate any fuse. External fuses
installed in the wiring to the inputs are essential.
If the input voltage remains below 0.8 Vi min or exceeds
1.1 Vi max (approx. values), an internally generated inhibit
signal disables the output(s). When checking this function
the absolute maximum input voltage rating Vi abs must be
carefully considered (see table: Electrical Input Data).
Between Vi min and the undervoltage lockout level the output
voltage may be below the value defined in table: Output
data (see: Technical Information: Measuring and Testing).
Table 3: Recommended fuse types
Series
12H
Schurter type
Part number
0001.2514
0001.2513
0001.2509
SPT
SPT
10 A 250 V
8 A 250 V
24H
48H
SPT 3.15 A 250 V
Reverse Polarity
The converter is not protected against reverse polarity at
the input. (Reverse polarity will cause the external fuse to
blow.)
REV. MAR 27, 2006
Page 4 of 19
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H Series Data Sheet
50 Watt DC-DC Cassette Converters
Electrical Output Data
General conditions
– TA = 25 °C, unless TC is specified.
– Connector pins 2 and 23 interconnected, R input not connected.
Table 4a: Output data
Output
5.1 V
12 V
15 V
Characteristics
Conditions
min
typ
max
5.20
min
typ
max
min
typ
max
Unit
V
1
Vo1
Output voltage
Vi nom, Io nom
5.00
11.76
11.10
12.24
12.90
13.80
14.70
13.90
15.30
16.10
17.25
Vo2/3
Vo2/3 0
-
-
Vi min to Vi max
Io2/3 = 0
Vo1 P
Vo2/3 P
Io nom
Io L
Output overvoltage
protection
7.5
-
21
25
25
31
Output current
Vi min to Vi max
see: Type Survey and Key Data
see fig.: Typical output voltage Vo1 versus output currents Io
T
TC max
Output current
C min to
limitation response
1
Vo1/2/3
Output Switch. freq. Vi nom, Io nom
30
60
50
60
70
100
200
50
75
80
mVpp
mV
voltage
noise
IEC/EN 61204
BW = 20 MHz
Total
200
200
ΔVo1U
Static line regulation Vi min to Vi nom
Vi nom to Vi max
50
50
100
150
100
150
Δ
Vo2/3 U
-
-
1
Io nom
ΔVo1 I
Static load regulation Vi nom
Io = Io nom to 0 2
150
150
ΔVo2/3 I
see: H2320/H3020
see: H2540/H3040
= ΔVo 2/3 vers. Io 2/3
= ΔVo 2/3 vers. Io 2/3
ΔVo1 Ic
Static cross load
regulation 3
Vi nom
Io = Io nom to 0 4
5
-
15
10
30
15
45
ΔVo2/3 Ic
see: H2320/H3020
see: H2540/H3040
= ΔVo 2/3 vers. Io 2/3
= ΔVo 2/3 vers. Io 2/3
Table 4b: Output data
Output
24 V
48 V
Characteristics
Conditions
min
typ
max
min
typ
max
Unit
Vo1
Output voltage
Overvoltage prot.
Output current
Vi nom, Io1 nom
23.52
24.48
47.04
48.96
V
Vo P
41
85
Io1 nom
Io1 L
Vi min to Vi max
TC min to TC max
see: Type Survey and Key Data
Output current
limitation response
see: Typical output voltage Vo1
versus output currents Io
1
Vo1/2/3
ΔVo1U
ΔVo1 I
Output Switch. freq. Vi nom, Io nom
30
75
50
20
35
40
mVpp
mV
voltage
noise
IEC/EN 61204
BW = 20 MHz
Total
200
150
Static line regulation Vi min to Vi nom
150
150
Vi nomto Vi max
Io1 nom
Static load regulation Vi nom
Io1 = Io1 nom to 0
150
150
1 With multiple-output models, the same condition for each output applies.
2 Condition for specified output. With multiple output models, other output(s) loaded with constant current Io = Io nom
.
3 Condition for non-specified output, individually tested, other output(s) loaded with constant current Io = Io nom
4 Multiple-output models.
.
REV. MAR 27, 2006
Page 5 of 19
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H Series Data Sheet
50 Watt DC-DC Cassette Converters
05119
Vo2/3 [V]
Vo2/3 0
Output Protection
Each output is protected against overvoltages which could
occur due to a failure of the internal control circuit. Voltage
suppressor diodes (which under worst case condition may
become a short circuit) provide the required protection.The
suppressor diodes are not designed to withstand externally
applied overvoltages. Overload at any of the outputs will
cause a shut-down of all outputs.
13
12
11
Io1 nom
0.5 • Io1 nom
Io1 = 0 A
05022
Vo1
Vo1 nom
Io nom
IoL1
Io2/3
Io2/3 nom
IoL2,IoL3
1.0
.95
0.25
0.75
0
0.5
1.0
Fig. 3
H2320/H3020: ΔVo2/3 (typ.) versus Io2/3 with different Io1
Io1
05120
Vo2/3 [V]
Vo2/3 0
Io2,Io3
0.5
16
15
14
Io1 nom
0.5 • Io1 nom
Io1 = 0 A
Io
Io nom
0
0.5
1.0
1.2
Fig. 2
Typical output voltage Vo1 versus output currents Io
Io2/3
Io2/3 nom
Parallel and Series Connection
0.25
0.75
0
0.5
1.0
Main outputs of equal nominal voltage can be connected in
parallel. It is important to assure that the main output of a
multiple-output converter is forced to supply a minimum
current of 0.1 A to enable correct operation of its own
auxiliary outputs.
Fig. 4
H2540/H3040: ΔVo2/3 (typ.) versus Io2/3 with different Io1
Outputs one and two of a double-output model may be
connected in parallel without
a
minimum current
requirement at the main output. Outputs two and three of a
triple-output model can be connected in parallel.
In parallel operation, one or more of the main outputs may
operate continuously in current limitation which will cause
an increase in case temperature. Consequently,
a
reduction of the maximum ambient temperature by 10 K is
recommended.
Main or auxiliary outputs can be connected in series with
any other output of the same or another converter. In series
connection, the maximum output current is limited by the
lowest current limit. Output ripple and regulation values are
added. Connection wiring should be kept as short as
possible.
If output terminals are connected together in order to
establish multi-voltage configurations, e.g. +5.1 V, 12 V
etc. the common ground connecting point should be as
close as possible to the connector of the converter to avoid
excessive output ripple voltages.
REV. MAR 27, 2006
Page 6 of 19
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H Series Data Sheet
50 Watt DC-DC Cassette Converters
Thermal Considerations
Io/Io nom
If a converter is located in free, quasi-stationary air
(convection cooling) at the indicated maximum ambient
temperature TA max (see table: Temperature specifications)
and is operated at its nominal input voltage and output
power, the temperature measured at the Measuring point of
case temperature TC (see: Mechanical Data) will approach
Forced cooling
1.0
0.9
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0
Convection cooling
the indicated value TC
after the warm-up phase.
max
TC max
However, the relationship between TA and TC depends
heavily on the conditions of operation and integration into a
system. The thermal conditions are influenced by input
voltage, output current, airflow and temperature of
surrounding components and surfaces. TA max is therefore,
contrary to TC max, an indicative value only.
TA [ C]
TA min
40
60
70
80
50
Caution: The installer must ensure that under all
operating conditions TC remains within the limits stated
in the table: Temperature specifications.
Fig. 5
Output current derating versus temperature for -2 units.
Notes: Sufficient forced cooling or an additional heat sink
allows TA to be higher than 50 °C (e.g. 65 °C) if TC max is not
exceeded.
Thermal Protection
A temperature sensor generates an internal inhibit signal
which disables the outputs if the case temperature exceeds
For -2 units at an ambient temperature TA of 65 °C with only
convection cooling, the maximum permissible current for
each output is approx. 50% of its nominal value as per
figure.
TC max. The outputs are automatically re-enabled if the
temperature drops below this limit.
Output Response
The reaction of the outputs is similar whether the input
voltage is applied or the inhibit is switched low.
05025
Output
Vo nom
An output voltage overshoot will not occur when the
converter is turned on or off.
0.95Vo nom
0.1
0
t
tr
tf
th
Vi
1
0
t
t
Fig. 6
Output response as a function of input voltage (on/off
switching) or inhibit control
Inhibit
1
0
Table 5: Output response time tr and tf
Type of Converter
tr at Po = 0 and tf at Po = Po nom
tr and tf at Po = 3/
4
Po nom
tr at Po = Po nom
Unit
ms
typ
max
typ
max
typ
max
H1001-2R
H1301-2R
H1501-2R
H1601-2R
H1901-2R
3
5
3
7
15
7
3
8
7
20
5
10
15
20
85
15
30
40
60
220
5
15
8
35
20
90
15
50
35
140
H2320-2
H2540-2
10
8
30
20
15
10
40
30
25
20
70
50
H3020-2
H3040-2
30
20
75
60
45
30
120
80
75
50
200
140
Conditions: R input not used. For multiple output modules the figures indicated in the table above relate to the output
which reacts slowest. All outputs are resistively loaded.Variation of the input voltage within Vi min to Vi max does not influence
the values.
REV. MAR 27, 2006
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Auxiliary Functions
i Inhibit for Remote On and Off
Iinh [mA]
Note: With open i input: Output is disabled (Vo = off).
V
inh = 2.4 V
V
inh = 0.8 V
The outputs of the module may be enabled or disabled by
means of a logic signal (TTL, CMOS, etc.) applied between
the inhibit input i and the negative pin of output 1 (Vo1–). In
systems with several units, this feature can be used, for
example, to control the activation sequence of the
converters. If the inhibit function is not required, connect
the inhibit pin 2 to pin 23 to enable the outputs (active low
logic, fail safe). For output response refer to: Output
2.0
1.6
1.2
0.8
0.4
Vo = on
Vo = off
Response.
0
–0.4
–0.8
06031
Vo+
i
Vi+
Iinh
Vinh [V]
–50
–30
–10
0
10
30
50
Fig. 8
Typical inhibit current Iinh versus inhibit voltage Vinh
Vinh
Vo–
Vi–
Fig. 7
Definition of Vinh and Iinh
.
Table 6: Inhibit data
Characteristics
Conditions
min
–50
2.4
typ
max
0.8
Unit
Vinh
Inhibit input voltage to keep
output voltage
Vo = on
Vo = off
Vi min to Vi max
TC min to TC max
VDC
50
I inh
Inhibit current
Vinh = 0
–60
–100
–220
µA
Vo1+
06088
R-Control for Output Voltage Adjustment
Note: With open R input, Vo ³ Vo nom
Vref
4000 Ω
R2
R1
.
As a standard feature, single-output models offer an
adjustable output voltage identified by letter R in the type
designation.
+
–
R
G
The output voltage Vo1 can either be adjusted with an
external voltage (Vext) or with an external resistor (R1 or R2).
The adjustment range is approximative 0 to 110% of
Vo nom. For output voltages Vo > Vo nom, the minimum input
voltage according to Electrical Input Data increases
Fig. 10
Voltage adjustment with external resistor R1 or R2
b) Vo ≅ 0 to 100% Vo nom, using R1 between R (14) and
proportionally to Vo/Vo nom
.
G (17):
Vo1+
R1
4000 Ω • Vo
06087
Vo ≅ Vo nom • –––––––––––
R1 ≅ ––––––––––
Vref
R1 + 4000 Ω
Vo nom - Vo
4000 Ω
R
+
–
c) Vo ≅ Vo nom to Vo max, using R2 between R (14) and
+
Vext
Vo1+ (20):
Vo max = Vo nom + 10%
G
Fig. 9
4000 Ω • Vo • (Vo nom – 2.5 V)
Voltage adjustment with external voltage Vext
R2 ≅ ––––––––––––––––––––––––
2.5 V • (Vo – Vo nom
)
a) Vo ≅ 0 to 110% Vo nom, using Vext between R (14) and
Vo nom • 2.5 V • R2
G (17):
Vo ≅ ––––––––––––––––––––––––––––––––
2.5 V • (R2 + 4000 Ω) – Vo nom • 4000 Ω
Vo
Vext
Vext ≅ 2.5 V • –––––
Vo ≅ Vo nom • –––––
Vo nom
2.5 V
Caution: To prevent damage, R2 should never be less
than 47 kΩ.
Caution: To prevent damage, Vext should not exceed
Note: R inputs of n models with paralleled outputs may be
paralleled, too, but if only one external resistor is to be
used, its value should be R1/n, or R2/n respectively.
8 V, nor be negative.
REV. MAR 27, 2006
Page 8 of 19
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H Series Data Sheet
50 Watt DC-DC Cassette Converters
Table 7a: R1 for Vo < Vo nom (conditions: Vi nom, Io nom, rounded up to resistor values E 96); R2 =
Vo nom = 5.1 V
Uo nom = 12 V
Vo nom = 15 V
Vo nom = 24 V
Vo nom = 48 V
Vo [V]
R1 [kΩ]
Vo [V]
R1 [kΩ]
Vo [V]
R1 [kΩ]
Vo [V]
R1 [kΩ]
Vo [V]
R1 [kΩ]
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
0.432
0.976
1.65
2.61
3.83
5.76
8.66
14.7
30.1
2.0
3.0
4.0
5.0
6.0
7.0
8.0
9.0
10.0
11.0
0.806
1.33
2.0
2.87
4.02
5.62
8.06
12.1
20.0
44.2
2.0
4.0
6.0
8.0
9.0
10.0
11.0
12.0
13.0
14.0
0.619
1.47
2.67
4.53
6.04
8.06
11.0
16.2
26.1
56.2
4.0
6.0
8.0
10.0
12.0
14.0
16.0
18.0
20.0
22.0
0.806
1.33
2.0
2.87
4.02
5.62
8.06
12.1
20.0
44.2
8.0
12.0
16.0
20.0
24.0
28.0
32.0
36.0
40.0
44.0
0.806
1.33
2.0
2.87
4.02
5.62
8.06
12.1
20.0
44.2
200.0
Table 7b: R2 for Vo > Vo nom (conditions: Vi nom, Io nom, rounded up to resistor values E 96); R1 =
Vo nom = 5.1 V
Vo [V] R2 [kΩ]
Vo nom = 12 V
Vo nom = 15 V
Vo nom = 24 V
Vo nom = 48 V
Vo [V]
R2 [kΩ]
Vo [V]
R2 [kΩ]
Vo [V]
R2 [kΩ]
Vo [V]
R2 [kΩ]
5.15
5.20
5.25
5.30
5.35
5.40
5.45
5.50
464
215
147
110
12.1
12.2
12.3
12.4
12.5
12.6
12.7
12.8
13.0
13.2
1780
909
619
464
383
316
274
249
200
169
15.2
15.4
15.6
15.8
16.0
16.2
16.4
16.5
1470
750
511
383
332
274
237
226
24.25
24.50
24.75
25.00
25.25
25.50
25.75
26.00
26.25
26.40
3160
1620
1100
825
715
590
511
453
402
383
48.5
49.0
49.5
50.0
50.5
51.0
51.5
52.0
52.5
52.8
6810
3480
2370
1780
1470
1270
1100
953
90.9
78.7
68.1
61.9
845
806
Display Status of LEDs
Vo1 > 0.95 to 0.98Vo1 adj
06090
Fig. 11
LEDs
"OK" and "i" status versus input voltage
OK
i
Conditions: Io ≤ Io nom, TC ≤ TC max, Vinh ≤ 0.8 V
Vi uv = undervoltage lockout, Vi ov = overvoltage lockout
Ui
Vi uv Vi min
Vi max Vi ov Vi abs
Vo1 > 0.95 to 0.98Vo1 adj
Vo1 < 0.95 to 0.98Vo1 adj
OK
LED "OK" status versus output current
Conditions: Vi min to Vi max, TC ≤ TC max, Vinh ≤ 0.8 V
Io
Io nom
IoL
i
LED "i"versus case temperature
Conditions: Vi min to Vi max, Io ≤ Io nom, Vinh ≤ 0.8 V
TC
TC max
TPTC threshold
Vinh threshold
i
LED "i"versus Vinh
Conditions: Vi min to Vi max, Io ≤ Io nom, TC ≤ TC max
Vi inh
+0.8 V
+2.4 V
+50 V
-50 V
LED off
LED Status undefined
LED on
REV. MAR 27, 2006
Page 9 of 19
www.power-one.com
H Series Data Sheet
50 Watt DC-DC Cassette Converters
Electromagnetic Compatibility (EMC)
battery-driven mobile applications. The H series has been
successfully tested to the following specifications:
A suppressor diode together with an input filter form an
effective protection against input transient voltages which
typically occur in most installations, but especially in
Electromagnetic Immunity
Table 8: Immunity type tests
Phenomenon
Standard 1
Level
Coupling
mode 2
Value
applied
Waveform
Source
imped.
Test
procedure
In
Per-
oper. form. 3
Electrostatic
discharge
(to case)
IEC/EN
61000-4-2
2
contact discharge 4000 Vp
1/50 ns
330 Ω
10 positive and
10 negative
discharges
yes
A
A
Electromagnetic IEC/EN
field
x
antenna
20 V/m
AM 80%
1 kHz
n.a.
26 to 1000 MHz
yes
yes
61000-4-3
Electrical fast
transient/burst
IEC/EN
61000-4-4
1
direct, i/c, +i/–i
500 Vp bursts of 5/50 ns 50 Ω
2.5 / 5 kHz over
1 min positive
1 min negative
transients per
coupling mode
15 ms; burst
period: 300 ms
Surge
IEC/EN
61000-4-5
1
i/c
500 Vp
1.2/50 µs
12 Ω
2 Ω
5 pos. and 5 neg.
surges per
yes
A
+i/–i
1 Related and previous standards are referenced in: Technical Information: Standards.
2 i = input, o = output, c = case.
3 A = Normal operation, no deviation from specifications, B = Normal operation,temporary deviation from specs possible.
Electromagnetic Emissions
Table 9: Emissions at Vi nom and Io nom
Series
Standard
CISPR 11/EN 55011, 1991
CISPR 22/EN 55022, 1987
-30 MHz
•30 MHz
<B
12H
24H
48H
<A
<B
<B
<B
<B
REV. MAR 27, 2006
Page 10 of 19
www.power-one.com
Mechanical Data
European
Projection
Dimensions in mm. Tolerances 0.3 mm unless otherwise indicated.
09050
Mounting holes for retaining clips V
Male connector H 11 according to DIN 41 612
0.6
100
Front plate
103
M 3; depth = 4 mm
(chassis mount)
Rear
face
Main face
Measurement point for
case temperatureTC
22
Mounting plane of
connector H11
(11.6)
88
38.7
111.2 0.8 3U
Back plate
0.1
94.5
95
0.5
17.25
12.17
7.09
ø 3.5
ø 4.0
0
OK (LED green)
Inhibit i (LED red)
Potentiometer
(option D or V)
Fig. 12
DC-DC converter in case H02, weight 770 g (approx.)
Case aluminium, black finish and self-cooling.
REV. MAR 27, 2006
Page 11 of 19
www.power-one.com
Immunity to Environmental Conditions
Table 10: Mechanical stress
Test method
Standard
Test conditions
Status
2
Ca
Ea
Eb
Fc
Damp heat
steady state
IEC/DIN IEC 60068-2-3
MIL-STD-810D section 507.2 Relative humidity:
Duration:
Temperature:
40 °C
Converter
not
operating
93 +2/-3
%
21 days
Shock
(half-sinusoidal)
IEC/EN/DIN EN 60068-2-27
MIL-STD-810D section 516.3 Bump duration:
Number of bumps:
Acceleration amplitude:
15 gn = 147 m/s2
11 ms
18 (3 each direction)
Converter
operating
Bump
(half-sinusoidal)
IEC/EN/DIN EN 60068-2-29
MIL-STD-810D section 516.3 Bump duration:
Number of bumps:
Acceleration amplitude:
10 gn = 98 m/s2
16 ms
6000 (1000 each direction)
Vibration
(sinusoidal)
IEC/EN/DIN EN 60068-2-6
MIL-STD-810D section 514.3
Acceleration amplitude:
0.15 mm (10 to 60 Hz)
2 gn = 20 m/s2 (60 to 150 Hz)
10 to 150 Hz
Frequency (1 Oct/min):
Test duration:
3.75 h (1.25 h each axis)
Table 11: Temperature specifications, values given are for an air pressure of 800 to 1200 hPa (800 to 1200 mbar)
Temperature
Standard -2
Option -7
Characteristics
Conditions
Operational2
min
max
50
min
–25
–25
–40
max
71
Unit
°C
TA
TC
TS
Ambient temperature 1
Case temperature 3
Storage temperature 1
–10
–10
–25
80
95
Not operational
100
100
3
1 MIL STD 810D section 501.2 and 502.2. 2 See: Thermal considerations. Overtemperature lockout at TC >95 °C (PTC).
Table 12: MTBF
Values at specified
Case Temperature
Model Types Ground Benign Unit
40 °C
MTBF 1
H1000
H2000
H3000
384'000
306'000
270'000
h
1 Calculated in accordance with MIL-HDBK-217E (calculation
according to edition F would show even better results)
Safety and Installation Instructions
10028
Connector pin Allocation
The connector pin allocation table defines the electrical
potentials and the physical pin positions on the H11
connector. Pin no. 26, the protective earth pin present on all
12H to 48H DC-DC converters is leading, ensuring that it
makes contact with the female connector first.
32 29 26 23 20 17 14 11 8
5 2
Fig. 13
View of male H11 connector.
Table 13: H11 connector pin allocation and designation
Electrical Determination
H1000
H2000
H3000
Pin
Ident
Pin
Ident
Pin
Ident
Inhibit control input
Safe Data or ACFAIL
2
5
i
2
5
i
2
5
i
D or V
D or V
D or V
Output voltage (positive)
Output voltage (negative)
8
11
Vo1+
Vo1–
8
11
8
11
Vo3+
Vo3–
Control input +
Control input –
14
17
R
G
Output voltage (positive)
Output voltage (negative)
14
17
Vo2+
Vo2–
14
17
Vo2+
Vo2–
Output voltage (positive)
Output voltage (negative)
20
23
Vo1+
Vo1–
20
23
Vo1+
Vo1–
20
23
Vo1+
Vo1–
Protective earthing 1
26
26
26
DC input voltage
DC input voltage
29
32
Vi+
Vi–
29
32
Vi+
Vi–
29
32
Vi+
Vi–
1 Leading pin (pregrounding)
REV. MAR 27, 2006
Page 12 of 19
www.power-one.com
H Series Data Sheet
50 Watt DC-DC Cassette Converters
Cleaning Agents
Installation Instructions
In order to avoid possible damage, any penetration of
liquids (e.g. cleaning fluids) is to be prevented, since the
power supplies are not hermetically sealed.
The H series DC-DC converters are components, intended
exclusively for inclusion within other equipment by an
industrial assembly operation or by professional installers.
Installation must strictly follow the national safety
regulations in compliance with the enclosure, mounting,
creepage, clearance, casualty, markings, and segregation
requirements of the end-use application. See also:
Technical Information: Installation and Application.
Standards and Approvals
12H to 48H DC-DC converters correspond to class I
equipment. All types are UL recognized according to UL
1950, UL recognized for Canada to CAN/CSA C22.2 No.
950-95 and TÜV approved to IEC/EN 60950 standards.
Connection to the system shall be made via the female
connector H11 (see: Accessories). Other installation
methods may not meet the safety requirements.
The units have been evaluated for:
•
•
Building in
Supplementary insulation between input and case and
double or reinforced insulation between input and
output, based on 250 VAC and 400 VDC
Operational insulation between output(s) and case
Operational insulation between the outputs
The use in a pollution degree 2 environment
Connecting the input to a primary or secondary circuit
with a maximum transient rating of 2500 V.
All DC-DC converters are provided with pin no. 26 ( ),
which is reliably connected with their case. For safety
reasons it is essential to connect this pin with the protective
earth of the supply system if required in: Safety of operator
accessible output circuit.
•
•
•
•
Ensure that a cassette failure (e.g. by an internal short-
circuit) does not result in a hazardous condition. See also:
Safety of operator accessible output circuit.
The DC-DC converters are subject to manufacturing
surveillance in accordance with the above mentioned UL,
CSA, EN and with ISO 9001 standards.
To prevent excessive current flowing into the cassette (e.g.
by an internal short-circuit), an external fuse suitable for the
application and in compliance with the local requirements
should be installed in the wiring to one or both input pins
(no. 29 and/or no. 32). See also: Input Fuse.
Protection Degree
Condition: Female connector fitted to the unit.
Important: Whenever the inhibit function is not in use,
pin no. 2 (i) should be connected to pin no. 23 (Vo1–) to
enable the output(s).
IP 40: All units, except those with option D or V with
potentiometer.
IP 20: All units fitted with option
potentiometer.
D or V with
Do not open the modules, or guarantee will be
invalidated.
Isolation
Make sure that there is sufficient airflow possible for
convection cooling. This should be verified by measuring
the case temperature when the unit is installed and
operated in the end-use application. The maximum
specified case temperature TC max shall not be exceeded.
See also: Thermal Considerations.
The electric strength test is performed as a factory test in
accordance with IEC/EN 60950 and UL 1950 and should
not be repeated in the field. Power-One will not honor any
guarantee/warranty claims resulting from electric strength
field tests.
If the end-product is to be UL certified, the temperature of
the main isolation transformer should be evaluated as part
of the end-product investigation.
Table 14: Isolation
Characteristic
Input to
case
Input to
output
Output
to case to output
Output
Unit
Electric
strength
test voltage
Required according to
IEC/EN 60950
1.5
2.1
2.8
2.0
3.0 1
4.2 1
5.6 1
4.0 1
0.5
0.7
1.4
1.0
-
kVrms
-
kVDC
Actual factory test 1 s
0.3
0.2
AC test voltage equivalent
to actual factory test
kVrms
Insulation resistance at 500 VDC
>300
>300
>300
>100 2
MΩ
1 In accordance with IEC/EN 60950 only subassemblies are tested in factory with this voltage.
2 Tested at 300 VDC.
For creepage distances and clearances refer to: Technical Information: Safety.
REV. MAR 27, 2006
Page 13 of 19
www.power-one.com
H Series Data Sheet
50 Watt DC-DC Cassette Converters
Safety of operator accessible output circuit
If the output circuit of a DC-DC converter is operator
accessible, it shall be a SELV circuit according to the IEC/
EN 60950 related safety standards.
Only voltage adaptation and rectification to the specified
input voltage range of the DC-DC converter is needed.
The following table shows some possible installation
configurations, compliance with which causes the output
circuit of the DC-DC converter to be a SELV circuit
according to IEC/EN 60950 up to a configured output
voltage (sum of nominal voltages if in series or +/–
configuration) of 36 V.
Since the H series DC-DC converters provide double or
reinforced insulation between input and output, based on a
rated primary input voltage of 250 VAC and 400 VDC only
operational insulation is needed between the AC mains and
the input of the DC-DC converter. This means that there is
no need for an electrical isolation between the AC mains
circuit and the DC-DC converter input circuit to cause the
output of an H series DC-DC converter to be a SELV circuit.
However, it is the sole responsibility of the installer to
assure the compliance with the relevant and applicable
safety regulations. More information is given in: Technical
Information: Safety.
Table 15: Safety concept leading to a SELV output circuit
Conditions Front end
DC-DC converter
Result
Nominal
supply
voltage
Minimum required grade
of isolation, to be provided voltage from the
by the AC-DC front end,
including mains supplied
battery charger
Nominal DC output Minimum required Measures to achieve the
safety status of the specified safety status of
Safety status
of the DC-DC
converter
front end
front end output
circuit
the output circuit
output circuit
Mains
Operational (i.e. there is
-400 V 1 (The
rated voltage
between any input
Primary circuit
Double or reinforced insulation,
based on 250 VAC and 400 VDC
(provided by the DC-DC converter)
and earthed case 2
SELV circuit
-250 VAC no need for electrical
isolation between the
mains supply voltage and pin and earth can
the DC-DC converter
input voltage)
be up to 250 VAC
or 400 VDC)
-400 V
Unearthed
Supplementary insulation, based
hazardous voltage on 250 VAC and 400 VDC, and
secondary circuit
double or reinforced insulation
based on the maximum nominal
output voltage from the front end
(both provided by the DC-DC con-
verter) and earthed case 3
1 The front end output voltage should match the specified operating input voltage range of the DC-DC converter.
2 The earth connection has to be provided by the installer according to the relevant safety standard, e.g. IEC/EN 60950.
3 The earth connection has to be provided by the installer according to the relevant safety standard, e.g. IEC/EN 60950. If the converter
case shall not be connected with earth, the front end output circuit has to be insulated from earth according to the relevant safety
standard by at least basic insulation, based on the maximum nominal output voltage from the front end, and insulated from the
converter case by at least supplementary insulation, based on the maximum nominal mains voltage. The converter case is then
considered to be a double-insulated accessible part.
Max. 250 VAC
or 400 VDC
10024
Fuse
Fuse
+
~
Mains
AC-DC
front
DC-DC
con-
verter
Battery
SELV
–
end
~
Max. 250 VAC
or 400 VDC
Earth
connection
Fig. 14
Schematic safety concept.
Use earth connection as per table: Safety concept leading
to a SELV output circuit. Use fuse according to: Installation
Instructions.
REV. MAR 27, 2006
Page 14 of 19
www.power-one.com
Description of Options
Table 16: Survey of options
Option
-7
Function of Option
Characteristic
Extended operational ambient temperature range
Input and/or output undervoltage monitoring circuitry
Input and output undervoltage monitoring circuitry
TA = –25 to 71°C
D 1
Safe data signal output (D1 to D8)
ACFAIL signal according to VME specifications ( V2, V3)
V 1 2
1 Option D excludes option V and vice versa
2 Only available with main output voltage Vo1 = 5.1 V
-7 Extended Temperature Range
Option -7 extends the operational ambient temperature
range from –10 to 50 °C (standard) to –25 to 71 °C. The
power supplies provide full nominal output power with
convection cooling.
D Undervoltage Monitor
The input and/or output undervoltage monitoring circuit
operates independently of the built-in input undervoltage
lockout circuit. A logic "low" (JFET output) or "high" signal
(NPN output) is generated at pin 5 as soon as one of the
monitored voltages drops below the preselected threshold
level Vt. The return for this signal is Vo1– (pin 23). The D
output recovers when the monitored voltage(s) exceed(s)
Vt+Vh. The threshold level Vt is adjustable by
a
potentiometer, accessible through a hole in the front cover.
Option D exists in various versions D1 to D8 as shown in
the following table.
Table 17: Undervoltage monitor functions
Output type
JFET NPN
Monitoring
Minimum adjustment range
of threshold level Vt
Typical hysteresis Vh [% of Vt]
for Vt min to Vt max
Vi
Vo1
Vti
Vto
Vhi
Vho
2.3 to 1
–
D1
D2
D3
D4
D5
D6
D7
D8
no
yes
yes
no
yes
no
–
3.5 V to 48 V 1
–
1
1
–
Vi min to Vi max
Vi min to Vi max
–
3.0 to 0.5
3.0 to 0.5
–
2
2
yes
yes
0.95 to 0.98 Vo1
0.95 to 0.98 Vo1
"0"
"0"
1 Threshold level adjustable by potentiometer (not recommended for mobile applications)
2 Fixed value between 95% and 98% of Vo1 (tracking)
11006
JFET output (D1 to D4):
Vo1+
Connector pin D is internally connected via the drain-
source path of a JFET (self-conducting type) to the
negative potential of output 1. VD ≤ 0.4 V (logic low)
corresponds to a monitored voltage level (Vi and/or Vo1)
<Vt.The current ID through the JFET should not exceed 2.5
mA.The JFET is protected by a 0.5 W Zener diode of 8.2 V
against external overvoltages.
R
p
I
D
D
V
D
Vi, Vo1 status
Vi or Vo1 < Vt
D output, VD
Vo1–
low, L, VD ≤ 0.4 V at ID = 2.5 mA
high, H, ID ≤ 25 µA at VD = 5.25 V
Fig. 15
Vi and Vo1 > Vt + Vh
Options D1 to D4, JFET output
11007
NPN output (D5 to D8):
Vo1+
Connector pin D is internally connected via the collector-
emitter path of an NPN transistor to the negative potential
of output 1. VD - 0.4 V (logic low) corresponds to a
monitored voltage level (Vi and/or Vo1) >Vt + Vh.The current
ID through the open collector should not exceed 20 mA.The
NPN output is not protected against external overvoltages.
VD should not exceed 40 V.
R
p
I
D
D
V
D
Vi, Vo1 status
Vi or Vo1 < Vt
D output, VD
Vo1–
high, H, ID ≤ 25 µA at VD = 40 V
low, L, VD ≤ 0.4 V at ID = 20 mA
Fig. 16
Vi and Vo1 > Vt +Vh
Options D5 to D8, NPN output
REV. MAR 27, 2006
Page 15 of 19
www.power-one.com
Threshold tolerances and hysteresis:
11021
VD
ΔVti
Vhi
If Vi is monitored, the internal input voltage after the input
filter is measured. Consequently this voltage differs from
the voltage at the connector pins by the voltage drop ΔVt i
across the input filter. The value of ΔVti depends upon the
input voltage range, threshold level Vt, temperature, and
input current. The input current is a function of the input
voltage and the output power.
VD high
VD low
Vi
Vti
Fig. 17
Definition of Vti, ΔVti and Vhi (JFET output)
Input voltage monitoring
NPN
VD
11008
VD high
3
3
3
3
VD low
t
t
0
ID
ID high
ID low
0
JFET VD
VD high
VD low
t
t
0
1
4
4
4
th
tlow min
tlow min
tlow min
thigh min
Vo1
Vo1 nom
1
th
1
0.95
0
Vi [V DC]
Vti +Vhi
Vti
t
0
Input voltage failure
Switch-on cycle
Input voltage sag
Switch-on cycle and subsequent
input voltage failure
Output voltage monitoring
NPN VD
2
VD high
3
3
VD low
t
t
0
ID
ID high
ID low
0
VD
JFET
VD high
VD low
t
t
0
4
tlow min
1 n.a.
Vo1
Vo1 nom
Vto +Vho
2 With output voltage monitoring the hold-up time th = 0
3 The D signal remains high if the D output is connected to
an external source.
Vto
0
4 tlow min = 40 to 200 ms, typically 80 ms
Output voltage failure
Fig. 18
Relationship between Vi, Vo1, VD, ID and Vo1/Vo nom versus time.
REV. MAR 27, 2006
Page 16 of 19
www.power-one.com
H Series Data Sheet
50 Watt DC-DC Cassette Converters
V ACFAIL signal (VME)
Formula for threshold level for desired value of th:
Available for units with Vo1 = 5.1 V.
2 • Po • (th + 0.3 ms) • 100
2
V ti =
–––––––––––––––––––––– + Vi min
This option defines an undervoltage monitoring circuit
for the input or the input and main output voltage equivalent
to option D, and generates the ACFAIL signal (V signal)
which conforms to the VME standard. The low state level of
the ACFAIL signal is specified at a sink current of IV = 48
mA to VV -0.6 V (open-collector output of a NPN transistor).
The pull-up resistor feeding the open-collector output
should be placed on the VME backplane.
Ci min • η
Formula for additional external input capacitor
2 • Po • (th + 0.3 ms) • 100
Ci ext = ––––––––––––––––––––– - Ci min
2
η • (Vti 2 – Vi min
)
where as:
Ci min = minimum internal capacitance [mF], according to
the table below
Ci ext = external input capacitance [mF]
After the ACFAIL signal has gone low, the VME standard
requires a hold-up time th of at least 4 ms before the 5.1 V
output drops to 4.875 V when the 5.1 V output is fully
loaded. This hold-up time th should be provided by an
external input capacitance. Consequently the working input
voltage and the threshold level Vt i should be adequately
above the minimum input voltage Vi min of the converter so
that enough energy is remaining in this capacitance.
Po
η
th
= output power [W]
= efficiency [%]
= hold-up time [ms]
Vi min = minimum input voltage [V]
Vti = threshold level [V]
If the input voltage is below the required level, an external
hold-up capacitor (Ci ext) should be added.
Remarks: The threshold level Vti of option V2 and V3 is
adjusted during manufacture to a value according to table
Undervoltage monitor functions, section Option D.
Table 18: Available internal input capacitance and factory
potentiometer setting of Vti with resulting hold-up time.
A decoupling diode should be connected in series with the
input to avoid the input capacitance discharging through
other loads connected to the same source voltage.
Types
Ci min
Vt i
12H
2.2
24H
0.75
19.5
0.87
48H
0.19
39
Unit
mF
9.5
VDC
ms
th
0.19
0.89
the monitored voltage(s) exceed(s) Vt + Vh. The threshold
level Vt is adjustable by a potentiometer accessible through
a hole in the front cover.
Option V operates independently of the built-in input
undervoltage lockout circuit. A logic "low" signal is
generated at pin 5 as soon as one of the monitored voltages
drops below the preselected threshold level Vt. The return
for this signal is Vo1– (pin 23). The V output recovers when
Versions V2 and V3 are available as shown below.
Table 19: Undervoltage monitor functions
V output
(VME compatible)
Monitoring
Minimum adjustment range
of threshold level Vt
Vti Vto
Typical hysteresis Vh [% of Vt]
for Vt min to Vt max
Vi
Vo1
no
Vhi
Vho
1
–
V2
V3
yes
yes
Vi min to Vi max
Vi min to Vi max
3.0 to 0.5
3.0 to 0.5
–
1
2
yes
0.95 to 0.98 Vo1
"0"
1 Threshold level adjustable by potentiometer (not recommended for mobile applications)
2 Fixed value between 95% and 98% of Vo1 (tracking), output undervoltage monitoring is not a requirement of VME standard
11009
V output (V2, V3):
Vo1+
Connector pin V is internally connected to the open
collector of an NPN transistor. The emitter is connected to
the negative potential of output 1. VV ≤ 0.6 V (logic low)
corresponds to a monitored voltage level (Vi and/or Vo1) <
R
p
I
V
Vt. The current IV through the open collector should not
exceed 50 mA. The NPN output is not protected against
external overvoltages. VV should not exceed 80 V.
V
V
V
Vi, Vo1 status
Vi or Vo1 < Vt
V output, UV
Vo1–
low, L, VV ≤ 0.6 V at IV = 50 mA
high, H, IV ≤ 25 µA at VV = 5.1 V
Fig. 19
Output configuration of options V2 and V3
Vi and Vo1 > Vt + Vh
REV. MAR 27, 2006
Page 17 of 19
www.power-one.com
Threshold tolerances and hysteresis:
11023
VV
ΔVti
Vhi
If Vi is monitored, the internal input voltage is measured
after the input filter. Consequently this voltage differs from
the voltage at the connector pins by the voltage drop ΔVti
across input filter and rectifier. The value of ΔVti depends
upon the input voltage range, threshold level Vt,
temperature, and input current. The input current is a
function of input voltage and output power.
VV high
VV low
Fig. 20
Vi
Vti
Definition of Vti, ΔVti and Vhi
Input voltage monitoring
2
2
2
tlow min
tlow min
tlow min
V2
VV
3
3
3
11010
VV high
4
2
4
2
VV low
t
t
0
tlow min
tlow min
V3
VV
3
3
3
VV high
VV low
0
1
1
th
th
Vo1
5.1 V
4.875 V
2.0 V
0
t
Vi [VDC]
Vti + Vhi
Vti
t
0
Input voltage failure
Switch-on cycle
Input voltage sag
Switch-on cycle and subsequent
input voltage failure
Output voltage monitoring
V2 VV
VV high
4
4
VV low
t
t
0
2
tlow min
V3 VV
VV high
3
3
4
VV low
0
Vo1
5.1 V
4.875 V
2.0 V
0
t
1 VME request: minimum 4 ms
Vi
2 tlow min = 40 to 200 ms, typically 80 ms
3 VV level not defined at Vo1 < 2.0 V
Vti + Vhi
Vti
4 The V signal drops simultaneously with the output voltage, if the
pull-up resistor RP is connected to Vo1+. The V signal remains
high if RP is connected to an external source.
t
0
Output voltage failure
Fig. 21
Relationship between Vi, Vo1, VV, IV and Vo1/Vo nom versus time.
REV. MAR 27, 2006
Page 18 of 19
www.power-one.com
H Series Data Sheet
50 Watt DC-DC Cassette Converters
Accessories
A variety of electrical and mechanical accessories are
available including:
– Front panels for 19" rack mounting, Schroff and Intermas
systems.
– Mating H11 connectors with screw, solder, fast-on or
press-fit terminals.
– Connector retention facilities.
– Code key system for connector coding.
– Flexible H11 PCB for mounting of the unit onto a PCB.
– Chassis mounting plates for mounting the 19" cassette to
a chassis/wall where only frontal access is given.
– Universal mounting bracket for DIN-rail or chassis
mounting.
For more detailed information please refer to Accessory
Products.
Front panels
H11 female connector,
Code key system
Flexible H11 PCB
Universal mounting bracket for DIN-rail mounting.
Mounting plate,
Connector retention clips
NUCLEAR AND MEDICAL APPLICATIONS - Power-One products are not designed, intended for use in, or authorized for
use as critical components in life support systems, equipment used in hazardous environments, or nuclear control systems
without the express written consent of the respective divisional president of Power-One, Inc.
TECHNICAL REVISIONS - The appearance of products, including safety agency certifications pictured on labels, may
change depending on the date manufactured. Specifications are subject to change without notice.
REV. MAR 27, 2006
Page 19 of 19
www.power-one.com
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