FS1001-7EPD4T [BEL]
DC-DC Regulated Power Supply Module, 1 Output, Hybrid, HEAT SINK, METAL, CASE S02, MODULE;
| 型号: | FS1001-7EPD4T |
| 厂家: | 
BEL FUSE INC. |
| 描述: | DC-DC Regulated Power Supply Module, 1 Output, Hybrid, HEAT SINK, METAL, CASE S02, MODULE 电源电路 |
| 文件: | 总33页 (文件大小:438K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Features
Input voltage ranges from 8 to 385 VDC and 85 to 264 VAC, 47-440 Hz
1or 2 isolated outputs up to 48 VDC
Class I equipment
• RoHS lead solder exemption compliant
• Extremely-wide input voltage range
• Input over- and undervoltage lockout
• Efficient input filter and built-in surge and transient
suppression circuitry
• Outputs: SELV, no-load, and short-circuit proof
• No derating over entire operating temperature range
• PCBs coated with protective lacquer
• Very high reliability
111
4.4"
3 U
60
2.4"
12 TE
168
6.6"
Safety according to IEC/EN 60950
Description
The S Series AC-DC and DC-DC converters represents a broad
and flexible range of power supplies for use in advanced
electronic systems. Features include high efficiency, high
reliability, low output voltage noise and excellent dynamic
response to load/line changes. LS models can be powered by
DC or AC with a wide-input frequency range (without PFC).
The case design allows operation at nominal load up to 71 °C in a
free-air ambient temperature. If forced cooling is provided, the
ambient temperature may exceed 71 °C, but the case temperature
must remain below 95 °C under all conditions.
A temperature sensor generates an inhibit signal, which disables
the outputs if the case temperature T exceeds the limit. The
c
The converter inputs are protected against surges and
transients. An input over- and undervoltage lockout circuitry
disables the outputs if the input voltage is outside of the
specified range. Certain types include an inrush current limiter
preventing circuit breakers and fuses from tripping at switch-on.
outputs are automatically re-enabled when the temperature drops
below the limit.
Various options are available to adapt the converters to individual
applications.
The converters may either be plugged into a 19" rack system
according to IEC 60297-3, or be chassis mounted. They are ideally
suited for Railway applications.
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 pin 18
(i). If the inhibit function is not used, pin 18 must be connected
with pin 14 to enable the outputs.
Important: For applications requiring compliance with IEC/EN
61000-3-2 (harmonic distortion), please use our LS4000 and LS5000
Series with incorporated power factor correction (PFC).
LED indicators display the status of the converter and allow for
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 standards IEC/EN
60950 and EN50155. They have been approved by the safety
agencies TÜV and UL (for USA and Canada).
Table of Contents
Page
Page
Description ................................................................................1
Model Selection ........................................................................2
Part Number Description and Product Marking ........................3
Functional Description ..............................................................4
Electrical Input Data..................................................................5
Electrical Output Data ..............................................................8
Auxiliary Functions..................................................................12
Electromagnetic Compatibility (EMC) ....................................15
Immunity to Environmental Conditions ..................................17
Mechanical Data ....................................................................18
Safety and Installation Instructions ........................................19
Description of Options ............................................................23
Accessories ............................................................................32
EC-Declaration of Conformity ................................................33
APR 26, 2006 revised to SEP 25, 2006
Page 1 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Model Selection
Non-standard input/output configurations or special custom adaptions are available on request.
Table 1a: Model types AS
Output 1
Output 2
Input Voltage
- V
i max
Efficiency 1
Options
V
I
V
I
V
η
o nom
o nom
o nom
o nom
i min
[VDC]
5.1
12
[A]
[VDC]
[A]
8 to 35 VDC
AS1001-7R
AS1301-7R
AS1501-7R
AS1601-7R
AS2320-7R
AS2540-7R
AS2660-7R
[%]
16
8
-
-
-
-
76
81
83
84
79
80
80
-9
D
V 2
15
6.5
4.2
4
-
-
24
-
-
P
12
12 3
15 3
24 3
4
T
15
3.2
2
3.2
2
B1, B2
24
Table 1b: Model types BS, CS, and FS
Output 1 Output 2
Input Voltage
- V
Eff. 1
η
Input Voltage
Eff. 1
η
Input Voltage
- V
Eff. 1 Options
η
V
I
V
I
V
V
- V
V
o nom o nom
o nom
o nom
i min
i max
i min
i max
i min
i max
[VDC]
5.1
12
[A]
16
8
[VDC]
[A]
14 to 70 VDC
BS1001-7R
BS1301-7R
BS1501-7R
BS1601-7R
BS2320-7R
BS2540-7R
BS2660-7R
[%]
28 to 140 VDC
CS1001-7R
CS1301-7R
CS1501-7R
CS1601-7R
CS2320-7R
CS2540-7R
CS2660-7R
[%]
20 to 100 VDC
FS1001-7R
FS1301-7R
FS1501-7R
FS1601-7R
FS2320-7R
FS2540-7R
FS2660-7R
[%]
-
-
-
-
77
83
85
86
80
82
82
77
83
84
85
80
82
82
77
83
84
86
80
82
82
-9
E 4, -9E 4
V 2
15
6.5
4.2
4
-
-
24
-
-
P
12
12 3
15 3
24 3
4
T
15
3.2
2
3.2
2
B1, B2
24
Table 1c: Model types DS, ES, and LS
Output 1 Output 2
Input Voltage
Eff. 1
η
Input Voltage
Eff. 1
η
Input Voltage
Eff. 1 Options
η
V
I
V
I
V
- V
V
- V
V
- V
o nom o nom
o nom
o nom
i min
i max
i min
i max
i min
i max
[VDC]
[A]
[VDC]
[A]
44 to 220 VDC
[%]
67 to 385 VDC
[%]
88 to 372 VDC
[%]
85 to 264 VAC
LS1001-7R
5.1
12
15
24
12
15
24
16
8
-
-
-
-
DS1001-7R
DS1301-7R
DS1501-7R
DS1601-7R
DS2320-7R
DS2540-7R
DS2660-7R
79
84
86
86
81
82
83
----
--
78
83
84
85
80
81
81
E 4, -9E 4
ES1301-7R
ES1501-7R
ES1601-7R
ES2320-7R
ES2540-7R
ES2660-7R
83
84
86
81
83
83
LS1301-7R
LS1501-7R
LS1601-7R
LS2320-7R
LS2540-7R
LS2660-7R
D
V 2
6.5
4.2
4
-
-
-
-
P
12 3
15 3
24 3
4
T
3.2
2
3.2
2
B1, B2
1 Min. efficiency η at V
, I
, and TA = 25 °C (DC input for LS models). Typical values are approx. 2% better.
i nom o nom
2 Option V for S1001 models only.
3 Second output semi-regulated.
4 Option E only for CS, DS, ES, FS, and LS models; mandatory for all -9 models.
APR 26, 2006 revised to SEP 25, 2006
Page 2 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Part Number Description and Product Marking
C S 2 5 40 -9 E R D3 T B1
Input voltage range V :
i
8 - 35 VDC ................A
14 - 70 VDC .............. B
20 - 100 VDC .............. F
28 - 140 VDC ................C
44 - 220 VDC ................D
67 - 385 VDC .............. E
85 - 264 VAC or 88 - 372 VDC................ L
Series................................................................................S
Number of outputs ........................................................1, 2
Single output models:
Nominal voltage output 1 (main output), V
o1 nom
5.1 V ......0, 1, 2
12 V ................3
15 V ............4, 5
24 V ................6
Other voltages1 ............7, 8
Other specifications for
single output models1 ......01 - 99
Double output models:
Nominal voltage output 1 and 2
12, 12V ......................................................................20
15, 15V ......................................................................40
24, 24V ......................................................................60
Other specifications and additional features1 ......70 - 99
Operational ambient temperature range T :
A
–25 to 71 °C................-7
–40 to 71 °C................-9
Other 1 ....-0, -5, -6
Auxiliary functions and options:
Inrush current limiter ......................................................E 3
Output voltage control input ..........................................R 2
Potentiometer (output voltage adjustment) ....................P 2
Undervoltage monitor (D0 - DD, to be specified) ..........D 4
ACFAIL signal (V0, V2, V3, to be specified) ..................V 4
Current share ....................................................................T
Cooling plate standard case ..........................................B1
Cooling plate for long case (220 mm) 1 ..........................B2
1 Customer-specific models.
2 Feature R excludes option P and vice versa.
3 Option E available for CS, DS, ES, FS, and LS models; mandatory for all -9 model types.
4 Option D excludes option V and vice versa; option V available for S1001 models only.
Example:
CS2540-9ERD3TB1: DC-DC converter, input voltage range 28 - 140 V, double output, each providing 15 V/3.2 A,
equipped with inrush current limiter, R input (voltage adjust), undervoltage monitor D3, current share, and a cooling plate
B1. Ambient temperature –40 to 71 °C.
Product Marking
Basic type designation, applicable approval marks, CE mark, warnings, pin allocation, Power-One patents, and company logo.
Identification of LEDs, test sockets, and potentiometer.
Specific type designation, input voltage range, nominal output voltages and currents, degree of protection, batch no., serial no., and
data code including production site, modification status, and date of production.
APR 26, 2006 revised to SEP 25, 2006
Page 3 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Functional Description
respect to the maximum admissible output currents, the control
signal for the primary switching transistor.
The input voltage is fed via an input fuse, an input filter, a bridge
rectifier (LS), and an inrush current limiter 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
ripple smoothed by a power choke and output filter. The control
The second output of double-output models is controlled by the
main output but has independent current limiting. If the main output
is driven into current limitation, the second output voltage will fall as
well and vice versa.
logic senses the main output voltage V
and generates, with
o1
P
03057-022706
16
18
R
i
26
5
Y
N
Vi+
28
20 D/V
2
T
22
12
4
4
1
S+
Y
Y
Vo+
Vo–
6
8
10
3
30
32
5
L
Vi–
S–
14
Y
24
–
+
Fig. 1
Block diagram of single output converters AS - LS1000
P
03058-022706
16
R
26
18 i
20 D
Y
5
N
Vi+
28
2
T
22
12
4
1
Y
Y
Vo1+
14
4
Vo1–
Vo2+
Y
3
6
30
32
5
L
Vi–
8
Vo2–
Y
Y
10
24
–
+
Fig. 2
Block diagram of symmetrical double output converters AS - LS2000
1 Transient suppressor (VDR) in CS, DS, ES, FS, LS models
2 Suppressor diode in AS, BS, CS, FS models
3 Inrush current limiter in CS, DS, ES, LS (NTC resistor or option E circuit)
4 Bridge rectifier (LS only)
5 LS models
APR 26, 2006 revised to SEP 25, 2006
Page 4 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Electrical Input Data
General Conditions
– TA = 25 °C, unless TC is specified.
– Pin 18 connected to pin 14, R input not connected, V adjusted to V
(option P)
o nom
o
– Sense line pins S+ and S– connected to Vo+ and Vo–, respectively.
Table 2a: Input data
Input
AS
BS
FS
Characteristics
Conditions
min
typ max
min
typ max
min
typ max
Unit
V
V
Operating input voltage
Nominal input voltage
Input current
I
T
= 0 - I
8
35
15
14
70
30
20
100
VDC
i
o
o nom
- T
C max
C min
50
2.6
2.5
1.5
i nom
1
I
V
V
, I
7.5
4.3
A
i
i nom o nom
- V
P
P
No-load input power
Idle input power
2.5
2.5
W
i0
i min
i max
converter inhibited
1.5
1.5
i inh
R
C
V
Input resistance
65
0
100
70
0
mΩ
μF
i
i
Input capacitance
Conducted input RFI
Radiated input RFI
1040
A
370
B
1500
B
EN 55022
i RFI
V
, I
i nom o nom
A
A
B
V
Input voltage limits
without damage
40
0
80
100
VDC
i abs
Table 2b: Input data
Input
CS
DS
ES
LS
Characteristics
Conditions
min typ max min typ max min typ max min typ max Unit
V
V
Operating input voltage
I
T
= 0 - I
28
140
44
220
67
385
88
85 4
372 VDC
264 4 VAC
VDC
i
o
o nom
- T
C max
C min
Nominal input voltage
Input current
60
110
1.1
220
310
0.4
i nom
1
I
i
V
V
, I
2.1
0.55
A
i nom o nom
- V
P
No-load input power
Idle input power
2.5
1.5
2.5
1.5
2.5
1.5
2.5
4.5
W
i0
i min
i max
P
converter inhibited
i inh
R
R
C
Input resistance
150
170
180
480
mΩ
Ω
i
NTC resistance 2
Input capacitance
Conducted input RFI
Radiated input RFI
1
830
B
2
330
B
4
270
B
4
270
B
NTC
i
μF
EN 55022
V
V
i RFI
i abs
V
, I
i nom o nom
B
B
B
A
Input voltage limits
without damage
0
154
0
400 3
0
400 -400
400 VDC
1 For double output models both outputs loaded with I
.
o nom
2 Valid for -7 versions without option E. This is the nominal value at 25 °C and applies to cold models at initial switch-on cycle. Subsequent
switch-on/off cycles increase the inrush current peak value.
3 For 1 s max.
4 AC operating frequency range is 47 to 440 Hz (440 Hz for 115 V mains). For frequencies ≥ 63 Hz refer to Safety and Installation Instructions.
Input Transient Protection
tolerance of –30% to 25%.
A suppressor diode and/or a VDR (depending on input voltage
range) together with the input fuse and a symmetrical input filter
form an effective protection against high input transient voltages
which typically occur in most installations, but especially in
battery-driven mobile applications.
In certain applications, surges according to RIA 12 are
specified in addition to those defined in IEC 60571-1. The
power supply must not switch off during these surges and
since their energy can practically not be absorbed an
extremely wide input range is required. The ES input range
for 110 V batteries has been designed and tested to meet
this requirement.
Nominal battery voltages in use are: 12, 24, 36, 48, 60, 72, 110,
and 220 V. In most cases each nominal value is specified in a
APR 26, 2006 revised to SEP 25, 2006
Page 5 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
The inrush current peak value (initial switch-on cycle) can be
determined by following calculation:
Input Fuse
A fuse mounted inside the converter protects the module against
severe defects. This fuse may not fully protect the module when
the input voltage exceeds 200 VDC! In applications where the
converters operate at source voltages above 200 VDC an
external fuse or a circuit breaker at system level should be
installed!
Vi source
Iinr p = ––––––––––––––––
(Rs ext + Ri + RNTC
)
05109_060805
Table 3: Fuse Specification
Rs ext
Iinr p
Ri
RNTC
Model
Fuse type
Reference
Rating
+
AS 1
BS 1
CS 2
DS 2
ES 2
FS 2
LS 2
fast-blow
fast-blow
slow-blow
slow-blow
slow-blow
slow-blow
slow-blow
Little fuse 314 30.0 A, 125 V
Little fuse 314 25.0 A, 125 V
Ci int
Vi source
SPT
SPT
SPT
SPT
SPT
12.5 A, 250 V
8 A, 250 V
4 A, 250 V
16 A, 250 V
4 A, 250 V
Fig. 4
Equivalent circuit for input impedance
1 Fuse size 6.3 x 32 mm
2 Fuse size 5 x 20 mm
Static Input Current Characteristic
Inrush Current
The CS, DS, ES, and LS models (not -9, not option E)
incorporate an NTC resistor in the input circuitry, which at initial
turn-on reduces the peak inrush current value by a factor of 5 to
10. Subsequent switch-on cycles within short periods increase
the inrush current due to the hotter NTC resistor.
Ii [A]
04037_011906
20
10
5
Ii inr [A]
AS
BS
04038_110705
150
2
1
FS
CS
100
DS
ES
0.5
CS
ES, LS
DS
Vi
1
2
3
4
5
6
Vi min
50
0
LS (DC input)
Fig. 5
Typical input current versus relative input voltage
Reverse Polarity
2
3 t [ms]
1
The converters (except LS) are not protected against reverse
polarity at the input, but in general, only the input fuse will trip. LS
models are fully protected due to the built-in bridge rectifier.
Fig. 3
Typical inrush current versus time at Vi max, Rext = 0.
Input Under-/Overvoltage Lockout
For AS, BS, and FS as well as for application-related values
use the formula given in this section to get realistic results.
If the input voltage remains below approx. 0.8 V
or exceeds
i min
, an internally generated inhibit signal disables
approx. 1.1 V
i max
the output(s). When checking this function the absolute maximum
input voltage rating V should be considered! Between V
i abs
i min
and the undervoltage lockout level the output voltage may be
below the value defined in table: Electrical Output Data.
APR 26, 2006 revised to SEP 25, 2006
Page 6 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Hold-up Time Versus Relative Input Voltage
t
h [ms]
04041_011906
ES
CS
FS
DS
100
th [ms]
04049_011906
100
10
AS
BS
10
1
Vi
Vi min
V
2
–––i––
Vi min
0.30
1
2
3
4
5
6
1
2
3
4
5
6
Fig. 6a
Typical hold-up time th versus relative input voltage
Vi/Vi . The DC-DC converters require an external
series diode in the input path if other loads are connected
to the same input supply lines.
Fig. 6b
Typical hold-up time th versus relative AC input voltage (LS
models)
min
APR 26, 2006 revised to SEP 25, 2006
Page 7 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Electrical Output Data
General Conditions
– T = 25 °C, unless T is specified.
A
C
– Pin 18 (i) connected to pin 14 (S–/Vo1–), V adjusted to V
(option P), R input not connected.
o
o nom
– Sense line pins 12 (S+) and 14 (S–) connected to Vo1+ and Vo1–, respectively.
Table 4a: Output data: single output models
Output
AS-LS1001
5.1 V
AS-LS1301
12 V
AS-LS1501
15 V
AS-LS1601
24 V
V
o nom
Characteristics
Conditions
min typ max
min typ max
min typ max
min typ max
Unit
V
V
Output voltage
V
, I
5.05
5.15 11.88
12.12 14.85
15.15 23.76
24.24
V
o
i nom o nom
Overvoltage protection
(suppressor diode)
Output current nom 1
7.6
16
21
8
26.5
6.5
43.5
4.2
o P
V
- V
- T
I
A
i min
C min
i max
C max
o nom
T
I
Output current limit 2
V
- V
, I
16.2
8.2
6.7
4.4
o L
i min
i max
v
Output Switching freq. V
noise 5
10 6
50
5 6
50
5 6
60
5 6
90
mV
pp
o
i nom o nom
Total incl.
spikes
BW = 20 MHz
ΔV
ΔV
v
Static line regulation
with respect to V
V
V
i min - i max
15
20
25
30
mV
o u
I
i nom
o nom
Static load regulation
V
,
-20
-25
-30
-40
o I
i nom
(0.1 - 1) I
o nom
Dynamic
load
Voltage
V
I
,
100
0.4
100
0.5
100
0.5
100
0.5
i nom
o d
deviation 3
↔ 0.5I
o nom
o nom
regulation 5
t
Recovery
time 3
ms
d
α
Temperature coefficient
of output voltage 4
T
I
- T
0.02
0.02
0.02
0.02
%/K
C min
C max
,
vo
o nom
1 If the output voltages are increased above Vo nom through R-input control, option P setting, remote sensing or option T, the output
current should be reduced accordingly so that Po nom is not exceeded.
2
See: Output Voltage Regulation.
3
See: Dynamic Load Regulation.
4
For battery chargers a defined negative temperature coefficient can be provided, see Accessories.
5
Measured according to IEC/EN 61204.
6 LS models have an additional low-frequency ripple at twice the input frequency (< 5mV ).
pp
APR 26, 2006 revised to SEP 25, 2006
Page 8 of 33
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S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Table 4b: Output data: double output models
Output
AS-LS2320
12 V/12 V
AS-LS2540
15 V/15 V
V
o nom
Characteristics
Conditions
Output 1
min typ max
11.88
Output 2
Output 1
Output 2
min typ max
min typ max
min typ max Unit
1
V
V
Output voltage
V
, I
12.12 11.76
12.24 14.85
15.15 14.70
15.30
V
o
i nom o nom
Overvoltage protection
(suppressor diode)
19
19
4
24
24
o P
I
Output current nom 2
V
T
- V
i max
C min
4
3.2
3.2
A
o nom
i min
- T
C max
I
Output current limit 6
V
- V
4.2
4.2
3.4
3.4
o L
i min
i max
v
Output Switching freq.
noise 3
V
, I
5 7
40
5 7
40
5 7
50
5 7
50
mV
o
i nom o nom
pp
Total including BW = 20 MHz
spikes
6
6
ΔV
ΔV
v
Static line regulation
with respect to V
V
- V
i min i max
20
25
mV
o u
I
I
i nom
o1 nom, o2 nom
6
6
Static load regulation
V
, I
,
-40
-50
o I
i nom o2 nom
(0.1 - 1) I
o1 nom
Dynamic
load
Voltage
V
,
100
0.2
150
100
0.2
150
o d
i nom
deviation 4
I
↔ 0.5I
,
o1 nom
o1 nom
regulation 3
t
Recovery
time 4
0.5I
ms
d
o2 nom
α
Temperature coefficient
of output voltage 5
T
- T
C max
0.02
0.02
%/K
vo
C min
I
I
o1 nom, o2 nom
1 Same conditions for both outputs.
Table 4c: Output data: double output models
2 If the output voltages are increased above
Output
AS-LS2660
24 V/24 V
V
via R-input control, option P setting,
V
o nom
o nom
remote sensing or option T, the output currents
should be reduced accordingly so that P
Characteristics
Conditions
Output 1
Output 2
is
o nom
min typ max min typ max Unit
not exceeded.
1
3 Measured according to IEC/EN 61204.
4 See: Dynamic Load Regulation.
V
V
Output voltage
V
, I
23.76
24.24 23.52
24.48
V
o
i nom o nom
Overvoltage protection
(suppressor diode)
37
2
37
2
o P
5 For battery chargers a defined negative
temperature coefficient can be provided, see
Accessories.
6 See: Output Voltage Regulation of Double
Output Models.
7 LS models have an additional low-frequency
ripple at twice the input frequency (< 5 mV ).
pp
I
Output current nom 2
V
T
- V
i max
C min
A
o nom
i min
- T
C max
I
Output current limit 6
V
- V
2.2
2.2
o L
i min
i max
v
Output Switching freq.
noise 3
V
, I
i nom o nom
5 7
50
5 7
50
mV
o
pp
Total including BW = 20 MHz
spikes
6
ΔV
Static line regulation
with respect to V
V
I
- V
i max
o1 nom, o2 nom
30
mV
o u
i min
I
i nom
6
ΔV
Static load regulation
V
, I
,
-60
i nom
o I
o2 nom
(0.1 - 1) I
o1 nom
V
Dynamic
load
Voltage
V
,
100
0.2
150
o d
i nom
deviation 4
I
↔ 0.5I
,
o1 nom
o1 nom
regulation3
t
Recovery 0.5I
time 4
ms
d
o2 nom
α
Temperature coefficient
of output voltage 5
T
I
- T
C max
o1 nom, o2 nom
0.02
%/K
vo
C min
I
APR 26, 2006 revised to SEP 25, 2006
Page 9 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Thermal Considerations
Output Protection
If a converter is located in free, quasi-stationary air (convection
cooling) at the indicated maximum ambient temperature TA max
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. A red LED indicates the overload condition.
(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 the indicated value TC max after
the warm-up phase. However, the relationship between TA and
TC depends heavily on the conditions of operation and
Parallel or Series Connection
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,
Single or double-output models with equal nominal output voltage
can be connected in parallel without any precautions using
Option T (current sharing).
contrary to TC max, an indicative value only.
Single output models and/or main and second outputs of double-
output models can be connected in series with any other (similar)
output.
Caution: The installer must ensure that under all operating
conditions T remains within the limits stated in the table
C
Temperature specifications.
Notes:
Notes: Sufficient forced cooling or an additional heat sink allows T
– Parallel connection of double output models should include both,
main and second output to maintain good regulation of both
outputs.
A
to be higher than 71 °C (e.g., 85 °C) if T
C max
is not exceeded.
For -7 or -9 models at ambient temperature T = 85 °C with only
A
– Not more than 5 models should be connected in parallel.
convection cooling, and the maximum permissible current for each
output is approx. 40% of its nominal value as per the figure below.
– Series connection of second outputs without involving their main
outputs should be avoided as regulation may be poor.
– Rated output voltages above 36 V need additional measures in
order to comply with the safety requirements for SELV (Safe Extra
Low Voltage)
Io/Io nom
– The maximum output current is limited by the output with the lowest
current limitation if several outputs are connected in series.
Forced cooling
1.0
Output Voltage Regulation
0.9
0.8
0.7
The following figures apply to single-output or double-output
models with parallel-connected outputs.
Convection cooling
0.6
Vo
Vo nom
TC max
0.5
05098_050605
0.4
0.3
0.2
0.1
0.98
0
T [˚C]
A
T
50
60
70
80
90
100
A min
0.5
Fig. 7
Io1
Output current derating versus temperature for -7 and -9
models.
IoL
Thermal Protection
Io
Io nom
A temperature sensor generates an internal inhibit signal which
0
0.5
1.0
disables the outputs if the case temperature exceeds TC max
.
The outputs are automatically re-enabled when the temperature
drops below this limit.
Fig. 8
Output characteristic Vo1 vs. Io1 (typ.)
Continuous operation under simultaneous worst-case conditions
of the following three parameters should be avoided: minimum
input voltage, maximum output power, and maximum
temperature.
APR 26, 2006 revised to SEP 25, 2006
Page 10 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
05102
Vo
[V] Vo2
Vod
Vo 1%
Vo 1%
05106_070805
15.75
Io1 = 5.00 A
Io1 = 3.75 A
Io1 = 2.50 A
Vod
15.50
td
td
Io1 = 1.25 A
15.25
15.00
14.75
14.50
14.25
14.00
Io1 = 0.50 A
t
t
Io/Io max
1
0.5
≥ 10 μs
≥ 10 μs
0
Fig. 9
Typical dynamic load regulation of V
o
Io2
0
1
2
3
4
5
6
7
[A]
Output Voltage Regulation of Double Output Models
Fig. 11
AS - LS2540: ΔVo2 (typ.) vs. Io2 with different I01
Note: If output 2 is not used, we recommend connecting it in
parallel with output 1. This ensures good regulation and efficiency.
Output 1 is under normal conditions regulated to Vo1 nom
,
[V] Vo2
independent of output currents. Vo2 depends upon the load
distribution. If both outputs are loaded with more than 10% of Io
nom, the deviation of Vo2 remains within 5% of the value of Vo1.
05107_060805
26.0
Io1 = 3.0 A
Io1 = 2.0 A
Io1 = 1.0 A
Io1 = 0.5 A
Io1 = 0.3 A
25.5
25.0
24.5
24.0
23.5
23.0
The following 3 figures show the regulation with varying load
distribution.
Two outputs of an S2000 model connected in parallel will behave
like the output of an S1000 model.
[V] Vo2
05105_060805
12.6
Io1 = 6.0 A
Io1 = 4.5 A
Io1 = 3.0 A
12.4
Io1 = 1.5 A
Io2
[A]
12.2
12.0
11.8
11.6
11.4
11.2
Io1 = 0.6 A
0
0.5
1
1.5
2
2.5
3
3.5
4
Fig. 12
AS - LS2660: ΔVo2 (typ.) vs. Io2 with different I01
Io2
0
1
2
3
4
5
6
7
8
[A]
Fig. 10
AS - LS2320: ΔVo2 (typ.) vs. Io2 with different I01
APR 26, 2006 revised to SEP 25, 2006
Page 11 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
06001
Vo/Vo nom
1
Auxiliary Functions
i Inhibit for Remote On and Off
Note: With open i input the output is disabled.
0.1
t
t
0
The outputs 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
converters, this feature can be used to control the activation
sequence of the converters. If the inhibit function is not required,
connect the inhibit pin 18 to pin 14 to enable the outputs (active
low logic, fail safe).
tf
tr
Inhibit
1
0
Fig. 15
Typical output response as a function of inhibit control
06031
Sense Lines
Vo+
i
Vi+
(Only single output models)
Iinh
Important: Sense lines must always be connected! Incorrectly
connected sense lines may activate the overvoltage limitation,
resulting in a permanent short-circuit of the output.
Vinh
This feature allows for compensation of voltage drops across the
connector contacts and if necessary, across the load lines. If the
sense lines are connected at the load rather than directly at the
connector, the user should ensure that the voltage differences
specified in the table below are not exceeded. We recommend
connecting the sense lines directly at the female connector.
Vo–
Vi–
Fig. 13
Definition of V
and I
.
inh
inh
Table 5: Inhibit characteristics
To ensure correct operation, both sense lines (S+ and S–) should
be connected to their respective power outputs (Vo1+ and Vo1–)
and the voltage difference between any sense line and its
respective power output pin (as measured on the connector)
should not exceed the following values:
Characteristic
Conditions
- V
min typ max Unit
V
Inhibit
voltage
V
V
= on
= off
V
–50
2.4
0.8
50
V
i min
i max
inh
o
o
I
Inhibit current
Rise time
Vinh = 0
–400 µA
ms
inh
t
30
depending on I
r
f
Table 6: Maximum voltage compensation allowed using
sense lines
t
Fall time
o
I
inh [mA]
Output
voltage
Total voltage difference Voltage difference
Vinh = 2.4 V
Vinh = 0.8 V
between sense lines and
their respective outputs
between
Vo– and S–
2.0
1.6
1.2
5.1 V
< 0.5 V
< 1.0 V
< 0.25 V
< 0.25 V
12, 15, 24 V
0.8
0.4
If the output voltages are increased above Vo nom via the R-input
Vo = on
Vo = off
control, option P setting, remote sensing or option T, the output
currents must be reduced accordingly so that Po nom is not
0
exceeded.
–0.4
–0.8
Vinh [V]
–50
–30
–10
0
10
30
50
Fig. 14
Typical inhibit current I
versus inhibit voltage V
inh
inh
APR 26, 2006 revised to SEP 25, 2006
Page 12 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Programmable Output Voltage (R-Function)
Notes:
– The R-Function excludes option P (output voltage adjustment by
potentiometer).
As a standard feature, the converters offer an adjustable output
voltage, identified by letter R in the type designation. The control
– If the output voltages are increased above V
via R-input
o nom
option P setting, remote sensing or option T, the output
input R (pin 16) accepts either a control voltage V
or a
ext
to adjust the desired output voltage. When not
control,
current(s) should
resistor R
be reduced accordingly so that P
is not
ext
connected, the control input automatically sets the output
voltage to V
o nom
exceeded.
.
– With double-output models the second output follows the value of
the controlled main output.
– In case of parallel connection the output voltages should be
individually set within a tolerance of 1 - 2%.
o nom
a) Adjustment by means of an external control voltage V
between pin 16 (R) and pin 14:
ext
The control voltage range is 0 - 2.75 VDC and allows an
output voltage adjustment in the range of approximately
0 - 110% V
.
o nom
V
o
05074_050905
V
= –––––– • 2.5 V (approximate formula)
ext
Vo1+
R
Vi+
V
o nom
b) Adjustment by means of an external resistor:
+
16
14
Depending upon the value of the required output voltage the
resistor shall be connected
Vext
S–
Either: Between pin 16 and pin 14 (V < V
an output voltage adjustment range of approximately
) to achieve
o nom
o
Vo1–
Vi–
Vi+
0 - 100% V
o nom
Vo1+
or: Between pin 16 and pin 12 (V > V
output voltage adjustment range of approximately 100 - 110%
) to achieve an
o
o nom
S+
R
12
R'ext
Rext
V
.
o nom
16
14
S–
Warning:
shall never exceed 2.75 VDC.
–
V
Vo1–
Vi–
ext
– The value of R'
shall never be less than the lowest value
Fig. 16
ext
as indicated in table R'
for (V > V )
o nom
Output voltage control for single-output models AS - LS1000.
ext
o
Table 7a: R
ext
for V < V
; approximative values (V
, I
, series E 96 resistors); R'ext = not fitted
o
o nom
i nom o nom
V
= 5.1 V
V
= 12 V
V
= 15 V
V
o
= 24 V
o nom
[V]
o nom
[V] 1
o nom
o nom
[V] 1
V
R
[kΩ]
V
R
[kΩ]
V
[V] 1
R
[kΩ]
V
R [kΩ]
ext
o
ext
0.432
o
ext
o
ext
0.5
2
3
4
5
6
7
8
9
10
11
4
6
8
10
12
14
16
18
20
22
0.806
1.33
2
2.87
4.02
5.62
8.06
2
4
6
8
9
10
11
12
13
14
4
8
0.619
1.47
2.67
4.53
6.04
8.06
4
6
8
10
12
14
16
18
20
22
8
12
16
20
24
28
32
36
40
44
0.806
1.33
2
2.87
4.02
5.62
8.06
12.1
20
44.2
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
0.976
1.65
2.61
3.83
5.76
8.66
14.7
30.1
200
12
16
18
20
22
24
26
28
11
12.1
16.2
26.1
56.2
20
42.2
1 First column: V or V , second column: outputs of double-output models in series connection
o1
o
APR 26, 2006 revised to SEP 25, 2006
Page 13 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Table 7b: R’
ext
for V > V
; approximative values (V
, I
, series E 96 resistors); Rext = not fitted
o
o nom
i nom o nom
V
= 5.1 V
V
= 12 V
V
= 15 V
V
= 24 V
o nom
[V]
o nom
[V] 1
o nom
[V] 1
o nom
[V] 1
V
R'
[kΩ]
V
o
R'
[kΩ]
V
R'
[kΩ]
V
R'
[kΩ]
ext
o
ext
ext
o
ext
o
5.15
5.2
5.25
5.3
5.35
5.4
432
215
147
110
88.7
75
12.1
12.2
12.3
12.4
12.5
12.6
12.7
12.8
13.0
13.2
24.2
1820
931
619
475
383
316
274
243
196
169
15.2
15.4
15.6
15.8
16.0
16.2
16.4
16.5
30.4
1500
768
523
392
316
267
232
221
24.25
24.5
24.75
25.0
25.25
25.5
25.75
26.0
26.25
26.4
48.5
3320
1690
1130
845
698
590
511
442
402
383
24.4
24.6
24.8
25.0
25.2
25.4
25.6
26.0
26.4
30.8
31.2
31.6
32.0
32.4
32.8
33.0
49.0
49.5
50.0
50.5
51.0
51.5
52.0
52.5
52.8
5.45
5.5
64.9
57.6
1 First column: V or V , second column: outputs of double-output models in series connection
o
o1
Test Jacks
Test jacks for measuring the output voltage V or V
06004_012006
are
o1
+
–
Vo2+
Vo2+
Vo2–
Vo2–
Vo1+
Vo1–
4
6
o
located at the front of the converter. The positive test jack is
protected by a series resistor (see: Functional Description,
block diagrams). The voltage measured at the test jacks is
slightly lower than the value at the output terminals.
24 V
30 V
48 V
8
Vo1
co
10
12
14
Rext R'ext
16
R
Fig. 17
Wiring for output voltage 24 V, 30 V, or 48 V (double-output
models) with both outputs connected in series. A ceramic
capacitor (C ) across the load reduces ripple and spikes.
o
Display Status of LEDs
Fig. 18
LEDs
Conditions: I ≤ I
06002_011106
Vo1 > 0.95 to 0.98Vo1 adj
"OK", "i" and "I "status versus input voltage
o L
OK
i
Io L
, T ≤ T ≤ 0.8 V
, V
= overvoltage lockout
i ov
o
o nom
C
C max inh
V
= undervoltage lockout, V
i uv
Vi
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
LEDs "OK" and "I "status versus output current
o L
Io L
Io
Conditions: V
- V
, TC ≤ TC
, V ≤ 0.8 V
i min
i max
max inh
Io nom
IoL
i
i
LED "i"versus case temperature
Conditions: V - V , I ≤ I
TC
, V
i max o o nom inh
≤ 0.8 V
i min
TC max
TPTC threshold
Vinh threshold
LED "i"versus V
inh
Vi inh
Conditions: Vi min - V
, I ≤ I , TC ≤ TC max
+0.8 V
+2.4 V
+50 V
i max o o nom
-50 V
LED off
LED Status undefined
LED on
APR 26, 2006 revised to SEP 25, 2006
Page 14 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Electromagnetic Compatibility (EMC)
typically occur in most installations; especially in battery-driven
mobile applications.
A suppressor diode and/or a metal oxide VDR (depending upon
type) together with an input fuse and an input filter form an
effective protection against high input transient voltages which
Electromagnetic Immunity
Table 8: Immunity type tests
Phenomenon
Standard
Surge/
Level
Coupling
mode 1
Value
applied
Waveform
Source
imped.
Test
procedure
In
Per-
oper. form. 2
RIA 12
Supply related
surge
A 3
+i/–i
3.5 V
batt
2/20/2 ms
0.1/1/0.1 s
10/100 µs
5/50 µs
0.2 Ω
1 positive
surge
yes
yes
A
B
(covers also
B
1.5 V
batt
IEC60571-1
and
Direct transient
C
D 4
+i/c, –i/c
960 V
p
5 Ω
5 pos. and 5 neg.
impulses
1800 V
p
EN50155:1995)
E
3600 V
p
0.5/5 µs
100 Ω
F
G 5
4800 V
p
0.1/1 µs
8400 V
p
0.05/0.1 µs
5/50 µs
Indirect coupled
transient
H
+o/c, –o/c,
1800 V
p
J
3600 V
p
0.5/5 µs
K
4800 V
p
0.1/1 µs
L
8400 V
0.05/0.1 µs
1/50 ns
p
Electrostatic
discharge
(to case)
IEC/EN
61000-4-2
4 6 contact discharge 8000 V
330 Ω
10 positive and
10 negative
discharges
yes
A
p
air discharge
15000 V
p
Electromagnetic IEC/EN
3 7
3
antenna
20 V/m
10 V/m
AM 80%
1 kHz
n.a.
n.a.
80 - 1000 MHz
yes
yes
A
A
field
61000-4-3
antenna
50% duty cycle,
200 Hz repetition
frequency
900 5 MHz
4 8
Fast
IEC/EN
capacitive, o/c
2000 V
bursts of 5/50 ns 50 Ω
2.5/5 kHz over
15 ms; burst
60 s positive
60 s negative
transients per
coupling mode
yes
A
p
transients/burst 61000-4-4
i/c, +i/–i
direct
4000 V
p
period: 300 ms
Surges
IEC/EN
61000-4-5
3
3
i/c
2000 V
2000 V
1.2/50 µs
1.2/50 µs
12 Ω
2 Ω
5 pos. and 5 neg.
surges per
coupling mode
yes
yes
A
A
p
+i/–i
p
RF conducted
immunity
IEC/EN
61000-4-6
3 9
i, o, signal wires
10 VAC
(140 dBμV)
AM 80%
1 kHz
150 Ω
0.15 - 80 MHz
1 i = input, o = output, c = case.
2 A = Normal operation, no deviation from specifications, B = Normal operation, temporary deviation from specs possible.
3 Only met with customer-specific models, CS (48 V battery) and ES (110 V battery) designed for an extended V range. Standard DS
i
models (110 V battery) will not be damaged, but overvoltage lockout will occur during the surge.
4 Corresponds to EN 50155:2001, waveform A, and EN 50121-3-2:2000, table 7.2.
5 Corresponds to EN 50155:2001, waveform B.
6 Corresponds to EN 50121-3-2:2000, table 9.2.
7 Corresponds to EN 50121-3-2:2000, table 9.1.
8 Corresponds to EN 50121-3-2:2000, table 7.1.
9 Corresponds to EN 50121-3-2:2000, table 7.4.
APR 26, 2006 revised to SEP 25, 2006
Page 15 of 33
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S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Electromagnetic Emission
CS1601-7R, Peak Vi+, Conducted 0,15
÷
30 MHz, Divina, 2006-10-01
dBμV
80
LS1301-7R, Peak Vi+, Conducted 0,15 ÷ 30 MHz, Divina, 2006-11-01
dBμV
80
70
60
50
40
30
20
10
0
70
EN 55022 B
EN 55022 B
60
50
40
30
20
10
0
0.2
0.5
1
2
5
10
20 MHz
0.2
0.5
1
2
5
10
20 MHz
Fig. 19b
Fig. 19a
Typical disturbance voltage (peak) at the input according to
Typical disturbance voltage (peak) at the input according to
EN 55011/22, measured at Vi nom and Io nom (DK1301-7R).
EN 55011/22, measured at Vi = 230 VAC and Io nom
,
(LK1001-7RD9B1).
Note: The Railway Standard, EN50121-3-2:2000 table 3, imposes
much higher limits, which are by far fulfilled.
[dBμV/m]
50
07077
A
40
B
30
20
10
[MHz]
0
Fig. 19c
Typical radiated electromagnetic field strength (quasi-peak)
according to EN 55011/22, normalized to a distance of 10 m,
measured at Vi nom and Io nom
.
APR 26, 2006 revised to SEP 25, 2006
Page 16 of 33
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S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Immunity to Environmental Conditions
Table 9: Mechanical and climatic stress
Test method
Standard
Test conditions
Status
2
Ca
Ea
Eb
Fc
Damp heat
steady state
IEC/EN 60068-2-78
MIL-STD-810D sect. 507.2
Temperature:
Relative humidity:
Duration:
40
93
°C
Converter
not
operating
+2/-3
%
56 days
IEC/EN 60068-2-27 1
MIL-STD-810D sect. 516.3
Acceleration amplitude:
Bump duration:
Number of bumps:
100 g = 981 m/s
n
6 ms
18 (3 each direction)
Converter
operating
2
Shock
(half-sinusoidal)
2
40 g = 392 m/s
n
6 ms
6000 (1000 each direction)
Bump
(half-sinusoidal)
IEC/EN 60068-2-29
MIL-STD-810D sect. 516.3
Acceleration amplitude:
Bump duration:
Number of bumps:
Converter
operating
Vibration
(sinusoidal)
IEC/EN 60068-2-6
MIL-STD-810D sect. 514.3
Acceleration amplitude:
0.35 mm (10 - 60 Hz)
2
Converter
5 g = 49 m/s (60 - 2000 Hz) operating
n
Frequency (1 Oct/min):
Test duration:
10 - 2000 Hz
7.5 h (2.5 h each axis)
2
Fn
Kb
Vibration
broad band
random
IEC/EN 60068-2-64
IEC/EN 60068-2-52
Acceleration spectral density: 0.05 g /Hz
Converter
operating
n
Frequency band:
Acceleration magnitude:
Test duration:
5 - 500 Hz
4.97 g
n rms
(digital control)
3 h (1 h each axis)
Salt mist, cyclic
(sodium chloride
NaCl solution)
Concentration:
Duration:
Storage:
Storage duration:
Number of cycles:
5% (30 °C)
Converter
not
operating
2 h per cycle
40 °C, 93% rel. humidity
22 h per cycle
3
1 Covers also EN50155/EN61373 (Category 1, body mounted Class B).
Table 10: Temperature specifications, valid for an air pressure of 800 - 1200 hPa (800 - 1200 mbar)
Temperature
Standard -7
Option -9
Characteristics
Conditions
min
max
71
min
–40
–40
max
71
Unit
TA
TC
Ambient temperature
Converter
Operating
–25
–25
°C
Case temperature1
95
95
TS
Storage temperature
Non-operational
–40
100
–55
100
1 Overtemperature lockout at TC > 95 °C
Failure Rates
Table 11: MTBF
Values at specified
case temperature
MTBF 1
Model types
AS - LS
Ground benign
40 °C
Ground fixed
Ground mobile Unit
50 °C
40 °C
70 °C
500 000
150 000
80 000
50 000
h
Device hours 2
500 000
1 Calculated in accordance with MIL-HDBK-217F.
2 Statistical values, based on an average of 4300 working hours per year and over 3 years in general field use.
APR 26, 2006 revised to SEP 25, 2006
Page 17 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Mechanical Data
European
Projection
7 TE
5 TE
Dimensions in mm. The converters are designed to be inserted
into a 19” rack, 160 mm long, according to IEC 60297-3.
3.27
(171.0 to 171.9)
50
M4
(+/–)
Test jacks
Option P (V )
o
to
Option D (V
)
Option D (V )
ti
LED i (red)
LED OK (green)
LED IoL (red)
Measuring point of
case temperature TC
= Ø 3.5
= Ø 4.1
d
8
152
8
60
Front plate
Main face
Back plate
168.5
Note:
– d ≥15 mm, recommended clearance to next part in order to
ensure proper air circulation at full power.
– Free air location: the converter should be mounted with fins in
a vertical position to achieve maximum airflow through the
heat sink.
Fig. 20
Aluminum case S02 with heat sink, black finish and self-cooling,
weight: Approx. 1.25 kg
09003_110705
7 TE
3.27
4 TE
50
5
158
M 4
Measuring point of
case temperature TC
5
47.2
17.3
133.4
168
Note: Long case with option B2, elongated by 60 mm for 220
mm rack depth, is available on request with a customer-specific
part number (no LEDs and no test jacks).
(171.0 to 171.9)
Fig. 21
Aluminum case S02 with option B1 (cooling plate), black finish and
self-cooling, weight: Approx. 1.15 kg
APR 26, 2006 revised to SEP 25, 2006
Page 18 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Installation Instructions
Safety and Installation Instructions
Connector Pin Allocation
The S Series 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.
The connector pin allocation table defines the electrical
potentials and the physical pin positions on the H15/H15 S4
connector. Pin no. 24 (protective earth) is a leading pin, ensuring
that it makes contact first.
Connection to the system shall be made via the female connector
H15 (see: Accessories). Other installation methods may not meet
the safety requirements.
10090
Fixtures for connector
retention clips
(see Accessories)
The converters are provided with pin 24 ( ), which is reliably
connected with the case. For safety reasons it is essential to
connect this pin to protective earth. See: Safety of Operator
Accessible Output Circuit.
Input pins 30 and 32 are internally fused. Since this fuse is
designed to protect the converter in case of an overcurrent and
does not necessarily cover all customer needs, an external fuse
suitable for the application and in compliance with the local
requirements might be necessary in the wiring to one or both input
potentials, pins 26 and 28, and/or 30 and 32.
32
4
Type H15
Fig. 22
View of converter’s male connector
Table 12: H15 connector pin allocation
Important: When the inhibit function is not in use, pin no. 18 (i)
should be connected to pin no. 14 (S–/Vo1–) to enable the output(s).
Do not open the converters, or guarantee will be invalidated.
Pin
No.
4
Connector type H15
AS to LS2000
AS to LS1000
Due to high current values, some models provide two internally
parallel connected contacts for certain paths (pins 4/6, 8/10, 26/28
and 30/32). It is recommended to connect load and supply to both
female connector pins of each path in order to keep the voltage
drop across the connector pins at an absolute minimum and to
avoid overstress of the connector contacts with currents higher
than 8 A.
Vo1+
Vo1+
Vo1–
Vo1–
S+
Pos. output 1
Vo2+
Vo2+
Vo2–
Vo2–
Vo1+
Vo1–
R 1
Pos. output 2
6
8
Neg. output 1
Neg. output 2
10
12
14
16
18
20
Sense
Sense
Pos. output 1
Neg. output 1
Control of V
S–
R 1
Make sure that there is sufficient airflow possible for convection
cooling. This should be verified by measuring the case
temperature when the converter is installed and operated in the
end-use application. The maximum specified case temperature
Control of V
o
o1
i
Inhibit
i
Inhibit
D 3
V 3
Save data
ACFAIL
D 3
Safe data
T
shall not be exceeded. See also Thermal Consid-erations.
Cmax
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.
22
24 2
26
28
30
32
T 5
Current share
Protective earth
Pos. input
Neutral line 4
Neg. input
Phase line 4
T 5
Current share
Protective earth
Pos. input
4
4
Check for hazardous voltages before altering any connections.
Vi+ N
Vi– L
Vi+ N
Vi– L
Neutral line 4
Ensure that a converter failure (e.g., by an internal short-circuit)
does not result in a hazardous condition. See also: Safety of
Operator-Accessible Output Circuits.
4
4
Neg. input
Phase line 4
1
Not connected, if option P is fitted.
2 Leading pin (pre-connecting).
3 Option D excludes option V and vice versa. Pin not connected unless
option D or V is fitted.
4 LS models.
5 Not connected, unless option T is fitted.
APR 26, 2006 revised to SEP 25, 2006
Page 19 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
LS-models Operated at Greater than 63 Hz
Railway Applications
Above 63 Hz the earth leakage current may exceed 3.5 mA, the
maximum specified in IEC/EN 60950. The built-in Y-caps are
only approved for ≤ 100 Hz. Frequencies greater than 350 Hz
The S Series converters have been designed according to
the Railway Standards EN50155 and EN50121. All boards
and components are coated with a protective lacquer.
are only permitted for V ≤ 200 VAC.
i
Cleaning Agents
Isolation
In order to avoid possible damage, any penetration of
cleaning fluids must be prevented, since the power
supplies are not hermetically sealed.
The electric strength test is performed in the factory as routine
test in accordance with EN 50116, IEC/EN 60950 and UL 1950
and should not be repeated in the field. Power-One will not
honor any guarantee claims resulting from electric strength field
tests.
Protection Degree
Condition: Female connector fitted to the converter.
IP 30: All models except those with option P and option
D,
Standards and Approvals
or V with potentiometer.
The converters are UL recognized according to UL 1950,
CAN/CSA C22.2 No. 950-95, and TÜV approved to IEC/EN
60950 standards.
IP 20: All models exhibiting a potentiometer.
The converters correspond to Class I equipment and have been
evaluated for:
•
•
Building in,
Basic insulation between input and case based on 250 V and
double or reinforced insulation or an earthed part between
input and output.
•
•
The use in a pollution degree 2 environment,
Connecting the input to a primary or secondary circuit which
is subject to a maximum transient rating of 2500 V.
The converters are subject to manufacturing surveillance in
accordance with the above mentioned UL and ISO 9001:2000
standards.
Table 13: Leakage Currents for LS-models
Characteristic
Class I
LS1000, LS2000
Unit
Maximum earth Permissible according to IEC/EN 60950
3.5
mA
leakage current
Specified value at 264 V, 50 Hz
1.43
Table 14: Isolation
Characteristic
Input to
case + output(s)
Output to
case
Output to
output
Unit
Electric
Factory test >1 s
2.8 1
1.4
1.0
0.14
0.1
kVDC
kVAC
strength
AC test voltage equivalent to factory test
2.0
test voltage
Insulation resistance at 500 VDC
300 2
300 2
100
MΩ
1 In accordance with EN 50116 and IEC/EN 60950 subassemblies are pretested with 5.6 kVDC.
2 Tested at 500 VDC.
APR 26, 2006 revised to SEP 25, 2006
Page 20 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Safety of Operator-Accessible Output Circuits
If the output circuit of a DC-DC converter is operator-accessible,
it shall be a SELV circuit according to safety standard
IEC/EN 60950.
of a 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.
The following table shows some possible installation
configurations, compliance with which causes the output circuit
Max. 150 VAC or VDC for AK, BK
10044_082605
Max. 250 VAC or VDC for CK, DK, EK, FK, LK
+
~
Mains
AC-DC
front
end
DC-DC
con-
verter
Fuse
Fuse
Battery
SELV
–
~
Max. 150 VAC or VDC for AK, BK
Max. 250 VAC or VDC for CK, DK, EK, FK, LK
Earth connection
Fig. 23
Schematic safety concept.
Use earth connection as per the table below.
Table 15: Safety concept leading to a SELV output circuit
Conditions Front end
Result
DC-DC converter
Result
Nominal
supply
voltage
Minimum required grade
DC output voltage Minimum required Types
from the front end safety status of the
front end output
Measures to achieve the Safety status
specified safety status of of the DC-DC
of insulation, to be pro-
vided by the AC-DC front
end, including mains
the output circuit
converter
circuit
output circuit
supplied battery charger
Mains
Functional
≤100 V. The
nominal voltage
between any
output pin and
earth is ≤150 V
(AC or DC)
Primary circuit
AS
BS
a) Double or reinforced
insulation based on
the mains voltage
SELV circuit
≤150 VAC (no electrical insulation
between the mains
supply voltage and the
DC-DC converter input)
(provided by the DC-DC
converter) AND
b) earthed case 3
Mains
≤250 VAC
≤250 V The
CS
DS
ES
FS
nominal voltage
between any
output pin and
earth is ≤250 V
(AC or DC)
Basic
≤250 V
Unearthed
hazardous voltage BS
secondary circuit
AS
a) Supplementary insulation,
based on 250 VAC AND
b) double or reinforced
insulation 2 (provided by
DC-DC converter) AND
c) earthed case 3
CS
DS
ES
FS
Earthed
hazardous voltage
secondary circuit
a) Double or reinforced
insulation 2 (provided by
the DC-DC converter) AND
b) earthed case 3
Double or reinforced
≤60 V
SELV circuit
4
≤120 V
TNV-3 circuit
Basic insulation (provided
by the DC-DC converter) 4
1 The front end output voltage should match the specified input voltage range of the DC-DC converter.
2 Based on the maximum nominal output voltage from the front end.
3 The earth connection has to be provided by the installer according to the relevant safety standards, e.g. IEC/EN 60950.
4 Earthing of the case is recommended, but not mandatory.
APR 26, 2006 revised to SEP 25, 2006
Page 21 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
If the output circuit of a AC-DC converter is operator-accessible,
it shall be a SELV circuit according to the related IEC/EN 60950
safety standards.
60950 up to a configured output voltage (sum of nominal voltages
if in series or +/– configuration) of 36 V.
If the LS converters are used as DC-DC converters, please refer to
the previous section.
The following table shows a possible installation configuration,
compliance with which causes the output circuit of an LS Series
AC-DC converter to be a SELV circuit according to IEC/EN
Table 16: Safety concept leading to a SELV output circuit
Conditions
AC-DC converter
Installation
Result
Nominal voltage
Grade of insulation
between input and output
provided by the AC-DC converter
Measures to achieve the resulting
safety status of the output circuit
Safety status of the AC-DC
converter output circuit
1
Mains
Double or reinforced
Earthed case and installation
SELV circuit
≤250 VAC
according to the applicable standards
1
The earth connection has to be provided by the installer according to the relevant safety standards, e.g. IEC/EN 60950.
10021
Fuse
+
SELV
–
~
Mains
AC-DC
con-
verter
Fuse
~
Earth connection
Fig. 24
Schematic safety concept. Use fuses and earth
connection as per: Installation Instructions and table:
Safety concept leading to a SELV output circuit.
APR 26, 2006 revised to SEP 25, 2006
Page 22 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Description of Options
Table 17: Survey of options
-9
E
Extended operational ambient temperature range
Electronic inrush current limitation circuitry
Potentiometer for fine adjustment of output voltage
Input and/or output undervoltage monitoring circuitry
Input (and output) undervoltage monitoring circuitry
Current sharing
TA = –40 to 71 °C
Active inrush current limitation for CK, DK, EK
P
D 1
V 1
Adjustment range +10/–60% of V (R input not connected)
o nom
Safe data signal output (versions D0 - DD)
2
,
ACFAIL signal according to VME specs (versions V0, V2, V3)
Interconnect T-pins if paralleling outputs (5 converters max.)
Replaces standard heat sink, allowing direct chassis-mounting
T
B1/B2
Cooling plate
1 Option D excludes Option V and vice versa.
2 Only available for Vo = 5.1 V.
Option -9: Extended Temperature Range
Table 18: Inrush current characteristics with option E
(DC-DC converters)
Option -9 extends the operational ambient temperature range
from –25 to 71 °C to –40 to 71 °C. The power supplies provide
full nominal output power with convection cooling. Option -9
excludes inrush current limitation by NTC.
Characteristics
CS
60
DS
110
7.4
ES
220
14.6
FS Unit
Vi nom, Io nom
Input voltage
48
V
A
Iinr p
Peak inrush
current
6.8
4.5
Option E: Inrush Current Limiter
CS/DS/ES/FS/LS types may be supplemented by an electronic
circuit (option E, replacing the standard built-in NTC) to achieve
an enhanced inrush current limiting function. Option E is
mandatory for -9 models.
tinr
Inrush current
duration
18
14
16
22
ms
V
, I
i max o nom
Input voltage
140
9.3
220
380
100
7.5
V
A
Iinr p
Peak inrush
current
14.5
25.3
CS models fitted with option E and option D6 (input voltage
monitoring) meet the standard ETS 300132-2 for 48 VDC supply
voltage. Option D6 (externally adjustable via potentiometer from
36.0 to 40.5 V) is necessary to disable the converter at low input
voltages, avoiding an excessive input current. Option D6
threshold level should be adjusted to 44.0 - 50.0 V for 60 V
nominal supply systems (refer to the description of option D). The
D output can be connected directly to the inhibit input.
tinr
Inrush current
duration
20
14
12
23
ms
Note: Subsequent switch-on cycles at startup are limited to max.
10 cycles during the first 20 seconds (cold model) and then to
max. 1 cycle every 8 seconds.
11039_052605
10017_111105
Capacitor Ci
fully charged
Normal operation
(current limiting
circuit is fully
I [A]
Rectifier (only AC-DC models)
Vi/RV
conducting)
Control
FET
Ii = Pi/Vi
t [ms]
RS
Ci
RI
0
Fig. 25
0
<30
Option E block diagram
Fig. 26
Current limiting resistance = R + R = 15 Ω (all models)
Inrush current with option E (DC-DC converters)
S
I
APR 26, 2006 revised to SEP 25, 2006
Page 23 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Table 19: Inrush current characteristics with option E (AC-DC converters)
Characteristics
LS
Unit
V = 230 VAC
min
–
typ
max
25.3
50
I
t
Peak inrush current
Inrush current duration
–
A
inr p
inr
–
35
ms
10065_102005
Ii [A]
20
15
10
5
Capacitor Ci
fully charged
Normal operation
(FET fully conducting)
0
–5
–10
t [ms]
–15
0
20
tinr 40
60
80
Fig. 27
Inrush current with option E
(LS models, Vi = 230 VAC, f = 50 Hz, P = P
)
i
o
o nom
APR 26, 2006 revised to SEP 25, 2006
Page 24 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Option P: Potentiometer
11036_012006
Vo+
Vi+
2
1
1
The potentiometer allows for an output voltage adjustment
in the range of +10/–60% of Vo nom
.
It is accessible
S+
T
through a hole in the front cover. This feature enables
compensation of voltage drops across the connector and
wiring. Option P is not recommended if models are
connected in parallel.
Converter
S–
Vo–
Vi–
Vi+
In double-output models both outputs are influenced by the
potentiometer setting. If option P is fitted, the R-pin 16 is
not connected.
Load
2
Vo+
S+
T
Note: If the output voltage is increased above Vo nom via the
1
1
R-input control, option P setting, remote sensing, or option T,
the output current(s) should be reduced accordingly so that
Po nom is not exceeded.
Converter
S–
Vo–
Vi–
Option T: Current Sharing
Max. 5 converters in parallel connection
This option ensures that the output currents are
approximately shared between all paralleled converters,
hence increasing system reliability. To use this facility,
simply interconnect the T pins of all converters and make
sure that the reference pins for the T-pin (S- for the S1000
or Vo1– for S2000) are also connected together. The load
1 Leads should have equal length and cross sections and should
run in the same cable loom.
2 Diodes for redundant operation.
Fig. 29
lines should have equal length and cross section to ensure
equal voltage drops. Not more than 5 converters should be
connected in parallel. The R-pins should be left in an open-
circuit condition. If not, prior to paralleling the Vo1 outputs
Paralleling of single-output models using option T with the
sense lines connected at the load
should be individually adjusted within 1 to 2%. Parallel
connection of converters with option
recommended.
P
is not
Power bus
+
–
11003_102005
Vo2+
Vo+
Load
Vo–
Vo2–
T
Converter
Vo+
Vo–
Vo1+
Vo1–
Vo+
Vo–
Load
Vo2+
Vo2–
T
Fig. 28
Converter
An example of poor wiring for connections in parallel
(unequal length of load lines)
Vo1+
Vo1–
Max. 5 converters in parallel connection
11037_012006
Fig. 30
Paralleling of double output models with the outputs
connected in series, and using option T in an application
with a power bus. Note that the signal at the T-pins is
referenced to Vo1-.
APR 26, 2006 revised to SEP 25, 2006
Page 25 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Option D: Undervoltage Monitor
are either adjustable by a potentiometer, accessible through a hole
in the front cover, or factory adjusted to a fixed value specified by
the customer.
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 20 as soon as one of the monitored voltages
Option D exists in various versions D0 - DD as shown in the
following table.
drops below the preselected threshold level V . The return for
t
this signal is Vo1–. The D output recovers when the monitored
voltage(s) exceed(s) V + V . The threshold levels V and V
t
h
ti
to
Table 20: Undervoltage monitor functions
Output type
Monitoring
Minimum adjustment range
Typical hysteresis V [% of V ]
h
t
of threshold level V
for V
- V
t
t min
t max
JFET
D1
NPN
D5
V
V
V
V
V
V
i
o1
ti
to
hi
ho
no
yes
yes
no
yes
no
-
3.5 - 40 V 1
-
2.5 - 0.6
1
1
D2
D6
V
V
-
- V
- V
-
3.4 - 0.4
-
i min
i min
i max
i max
2
2
D3
D7
yes
yes
yes
no
(0.95 - 0.985 V
(0.95 - 0.985 V
3.5 - 40 V 3
)
)
3.4 - 0.4
"0"
o1
o1
D4
D8
-
"0"
D0
D9
no
-
-
2.5 - 0.6
3, 4
3, 4
3, 4
1
yes
yes
yes
yes
V
V
V
V
- V
- V
- V
- V
-
3.4 - 0.4
-
i min
i min
i min
i min
i max
i max
i max
i max
yes
yes
yes
3.5 - 40 V 3
3.4 - 0.4
3.4 - 0.4
3.4 - 0.4
2.5 - 0.6
"0"
2
(0.95 - 0.985 V
3.5 - 40 V 1
)
o1
-
DD
2.5 - 0.6
1
2
Threshold level adjustable by potentiometer
Fixed value tracking if V is adjusted via R-input, option P or sense lines.
o1
3
4
The threshold level is permanently adjusted according to customer specification 2% at 25 °C. Any value within the
specified range is possible, but causes a new customer-specific type designation.
Adjusted at I
o nom
APR 26, 2006 revised to SEP 25, 2006
Page 26 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
11006
JFET output (D0 - D4):
Vo1+
Pin 20 (D) is internally connected via the drain-source path
of a JFET (self-conducting type) to Vo1+ or Vo+.
R
p
V
≤ 0.4 V (logic low) corresponds to a monitored voltage
D
I
D
level (V and/or V ) < V . The current I 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.
i
o1
t
D
D
V
D
V , V status
o1
D output, V
D
i
V or V < V
o1
low, L, V ≤ 0.4 V at I = 2.5 mA
D D
i
t
Vo1–
V and V > V + V
o1
high, H, I ≤ 25 µA at V = 5.25 V
D D
i
t
h
Fig. 31
Option D1 - D0: JFET output, I ≤ 2.5 mA
D
11007
NPN output (D5 - DD):
Vo1+
Pin 20 (D) is internally connected via the collector-emitter
path of an NPN transistor to Vo1+ or Vo+. V < 0.4 V
D
R
(logic low) corresponds to a monitored voltage level (V
p
i
I
D
and/or V ) > V +V . The current I through pin 20
o1
t
h
D
D
should not exceed 20 mA. This output is not protected
against external overvoltages. V should not exceed 40 V.
V
D
D
V , V status
o1
D output, V
D
i
V or V < V
o1
high, H, I ≤ 25 µA at V = 40 V
D D
Vo1–
i
t
V and V > V + V
o1
low, L, V ≤ 0.4 V at I = 20 mA
D D
Fig. 32
Option D5 - DD: NPN output, V ≤ 40 V, I ≤ 20 mA
i
t
h
o1
D
Table 21: D-output logic signals
Version of D
V < V resp. V < V
V > V + V resp. V > V
Configuration
JFET
i
t
o
t
i
t
h
o
t
D1, D2, D3, D4, D0
D5, D6, D7, D8, D9, DD
low
high
high
low
NPN
11021
VD
ΔVti
Vhi
Threshold tolerances and hysteresis:
If V is monitored, the internal input voltage after the input
i
VD high
filter is measured. Consequently, this voltage differs from
the voltage at the connector pins by the voltage drop ΔV
ti
across the input filter. The threshold levels of the D0 and
D9 options are factory-adjusted at nominal output current
I
and at T = 25 °C. The value of ΔV depends upon
o nom
A
ti
the input voltage range (CS, DS, ..), threshold level V ,
VD low
t
Vi
temperature and input current. The input current is a
function of the input voltage and the output power.
Vti
Fig. 33
Definition of V , ΔV and ΔV (JFET output)
ti t i hi
APR 26, 2006 revised to SEP 25, 2006
Page 27 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
D-signal with respect to input and output voltage versus time:
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
Vo1
Vo1 nom
Vto +Vho
Vto
1 Hold-up time see: Electrical Input Data
0
Output voltage failure
2 With output voltage monitoring, hold-up time t = 0.
h
Fig. 34
3 The signal will remain high if the D output is connected
to an external source.
Relationship between V , V , V , V /V
versus time
i
o1 o1 o nom
D
4 t
low min
= typically 130 ms.
APR 26, 2006 revised to SEP 25, 2006
Page 28 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Option V: ACFAIL Signal (VME)
Formula for the external input capacitor:
2 • P • (t + 0.3 ms) • 100
Available only for models with V = 5.1 V.
o
This option defines an undervoltage monitoring circuit for the
input and main output voltage. It generates an ACFAIL signal
(V signal) which conforms to the VME standard.
o
h
C
= –––––––––––––––––––––– – Ci min
i ext
2
2
η • (V
ti
– V
)
i min
The low state level of the ACFAIL signal is specified at a sink
where as:
current of I ≤ 48 mA to V ≤ 0.6 V (open-collector output of an
V
V
Ci min = internal input capacitance [mF]
NPN transistor). The pull-up resistor feeding the open-collector
output should be placed on the VME backplane.
Ci ext = external input capacitance [mF]
P
= output power [W]
o
After the ACFAIL signal has gone low, the VME standard
η
h
= efficiency [%]
= hold-up time [ms]
requires a hold-up time (t of at least 4 ms before the 5.1 V
h)
t
output drops to 4.875 V when the output is fully loaded. The
hold-up time is provided by the internal input capacitance.
Consequently, the working input voltage and the threshold level
1
Vi min = minimum input voltage [V]
Vti = threshold level [V]
(V should be adequately above the minimum input voltage
ti)
1
Min. input voltage according to Electrical Input Data. For output voltages
(V
of the converter so that enough energy is remaining in
i min)
the input capacitance. If the input voltage is below the required
level, an external hold-up capacitor (C ) should be added.
V
> V
, the minimum input voltage increases proportionally to
o
o nom
.
o nom
V /V
o
i ext
Remarks:
Option V2 and V3 can be adjusted by potentiometer to a threshold
level between V and V . A decoupling diode should be
Formula for threshold level for desired value of t :
h
i min
i max
2 • Po • (t + 0.3 ms) • 100
h
connected in series with the input of AS - FS converters to avoid
the input capacitance discharging through other loads connected
to the same source voltage.
2
V =
ti
––––––––––––––––––––– + V
i min
C
• η
i min
Table 22: Available internal input capacitance and factory potentiometer setting of V with resulting hold-up time
ti
Types
AS
0.83
9.5
BS
FS
1.2
39
CS
0.66
39
DS
0.26
61
ES
0.21
97
LS
0.21
120
6.4
Unit
mF
C
0.3
i min
V
19.5
0.1
VDC
ms
t i
t
0.1
5.3
1.9
1.8
4.3
h
V + V . The threshold level Vti is either adjustable by
Option V operates independently of the built-in input
undervoltage lockout circuit. A logic "low" signal is generated at
pin 20 as soon as one of the monitored voltages drops below the
preselected threshold level Vt. The return for this signal is Vo1–.
t
h
potentiometer, accessible through a hole in the front cover,
or adjusted during manufacture to a determined customer
specified value.
The V output recovers when the monitored voltage(s) exceed(s)
Versions V0, V2, and V3 are available as shown below.
Table 23: Undervoltage monitor functions
V output
(VME compatible)
Monitoring
Minimum adjustment range
of threshold level V
Typical hysteresis V [% of V ]
h
t
for V
- V
t
t min
t max
V
V
V
V
V
V
ho
i
o1
no
ti
to
hi
1
–
V2
V3
V0
yes
V
V
- V
- V
3.4 - 0.4
3.4 - 0.4
3.4 - 0.4
3.4 - 0.4
–
i min
i max
1
2
2
yes
yes
yes
yes
no
0.95 - 0.985 V
–
"0"
i min
i max
o1
3, 4
3, 4
V
V
- V
- V
–
i min
i min
i max
i max
yes
0.95 - 0.985 V
"0"
o1
1
Threshold level adjustable by potentiometer.
2 Fixed value between 95% and 98.5% of V (tracking).
o1
3 Adjusted at I
.
o nom
4
Fixed value, resistor-adjusted ( 2% at 25 °C) acc. to customer's specifications; individual type number is determined by Power-One.
APR 26, 2006 revised to SEP 25, 2006
Page 29 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
11009
V output (V0, V2, V3):
Vo1+
Connector pin V is internally connected to the open collector of
an NPN transistor. The emitter is connected to Vo1- or Vo-.
V
≤ 0.6 V (logic low) corresponds to a monitored voltage level
R
p
V
(V and/or V ) <V . The current I through the open collector
I
V
i
o1
t
V
should not exceed 50 mA. The NPN output is not protected
V
against external overvoltages. V should not exceed 60 V.
V
V
V
V , V status
o1
V output, V
V
low, L, V ≤ 0.6 V at I = 50 mA
V V
i
Vo1–
V or V < V
o1
i
t
Fig. 35
Output configuration of options V0, V2, and V3
V and V > V + V
o1
high, H, I ≤ 25 µA at V = 5.1 V
V V
i
t
h
11023
VV
ΔVti
Vhi
Threshold tolerances and hysteresis:
If V is monitored, the internal input voltage is measured after the
i
VV high
input filter. Consequently, this voltage differs from the voltage at
the connector pins by the voltage drop DV across the input
ti
filter. The threshold level of option V0 is adjusted during
manufacture at I
and T = 25 °C. The value of ΔV
o nom
A ti
depends upon the input voltage range (AS, BS, etc.), threshold
VV low
level V , temperature and input current. The input current is a
t
Vi
function of input voltage and output power.
Fig. 36
Vti
Definition of V , ΔV and V
ti ti hi
APR 26, 2006 revised to SEP 25, 2006
Page 30 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
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
1
2
VME request: minimum 4 ms
t = 40 - 200 ms, typically 80 ms
low min
4
4
VV low
t
t
0
3
4
V
level not defined at V < 2.0 V
o1
V
2
tlow min
V3 VV
VV high
The V signal drops simultaneously with the output voltage. If
the pull-up resistor R is connected to Vo1+. The V signal
3
3
4
P
remains high if R is connected to an external source.
P
VV low
0
Vo1
5.1 V
4.875 V
Fig. 37
2.0 V
0
Relationship between V , V , V , I and V /V
i
o1 V V
o1 o nom
t
versus time.
Vi
Vti + Vhi
Vti
t
0
Output voltage failure
Options B1/B2: Cooling Plate
(100% – η)
P
= –––––––––– • V • I
o o
Loss
η
Where a cooling surface is available, we recommend the use
of a cooling plate (option B1) instead of the standard heat sink.
The mounting system should ensure sufficient cooling
capacity to guarantee that the maximum case temperature
Efficiency η see: Model Selection
Elongated case for 220 mm rack depth: Option B2
Dimensions see Mechanical Data
T
is not exceeded.The cooling capacity is calculated by:
C max
APR 26, 2006 revised to SEP 25, 2006
Page 31 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
Accessories
A variety of electrical and mechanical accessories are available
including:
– Front panels for 19" DIN-rack: Schroff 16 TE /3U,
[HZZ00831] and 16 TE /6U [HZZ00832], or Intermas
16 TE /3U [HZZ00731].
– Mating H15/H15 S4 connectors with screw, solder, fast-on or
press-fit terminals.
– Cable connector housing: Screw version [HZZ00141] or
retention clip version [HZZ00142].
– Connector retention clips (2x) [HZZ01209].
– Connector retention brackets CRB [HZZ01216].
– Coding clips for connector coding [HZZ00202].
Chassis mounting brackets CMB-S
– Chassis mounting plate CMB-S [HZZ00616] for fastening to a
chassis with only front access.
– DIN-rail mounting assembly DMB-K/S [HZZ00615].
– Wall-mounting plate K02 [HZZ01213] for models with option
B1.
– Additional external input or output filters.
– Battery temperature sensor [S-KSMH...] for use of the
converter as a battery charger. Different battery charact-
eristics can be selected.
For additional accessory product information, see the accessory
data sheets listed with each product series or individually at
www.power-one.com through the following menus: “Select
Products”, “Download Data Sheets & Applications Notes”, or
with each model in the product overviews.
DIN mounting assembly DMB-K/S
H15 female connector,
code key system
20 to 30 Ncm
Front panels
Connector retention bracket CRB
Connector retention clip
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.
APR 26, 2006 revised to SEP 25, 2006
Page 32 of 33
www.power-one.com
S Series Data Sheet
100 Watt AC-DC and DC-DC Converters
EC Declaration of Conformity
We
Power-One AG
Ackerstrasse 56, CH-8610 Uster
declare under our sole responsibility that K and S Series AC-DC and DC-DC
converters carrying the CE-mark are in conformity with the provisions of the Low
Voltage Directive (LVD) 73/23/EEC of the European Communities.
Conformity with the directive is presumed by conformity wih the following
harmonized standards:
• EN 61204:1995 (= IEC 61204:1993, modified)
Low-voltage power supply devices, DC output - Perfomance characteristics
and safety requirements
• EN 60950:2000 (= IEC 60950:2000)
Safety of information technology equipment
The installation instructions given in the data sheet describe correct installation
leading to the presumption of conformity of the end product with the LVD. All K
and S Series AC-DC and DC-DC converters are components, intended
exclusively for inclusion within other equipment by an industrial assembly
operation or by professional installers. They must not be operated as stand alone
products.
Hence conformity with the Electromagnetic Compatibility Directive 89/336/EEC
(EMC Directive) needs not to be declared. Nevertheless, guidance is provided in
most product application notes on how conformity of the end product with the
indicated EMC standards under the responsibility of the installer can be achieved,
from which conformity with the EMC directive can be presumed.
Uster, 24 May 2005
Power-One AG
Rolf Baldauf
Johann Milavec
VP Engineering
Director Projects and IP
APR 26, 2006 revised to SEP 25, 2006
Page 33 of 33
www.power-one.com
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