Puls CD5.243 DC/DC Converter Guia De Especificação
CD5.243
CD-Series
DC/DC Converter 24V, 4A
22.7. P
ARALLEL
U
SE TO
I
NCREASE
O
UTPUT
P
OWER
Unit A
Input
Output
Unit B
-
+
-
+
+
-
Input
Output
Load
The DC/DC-converter can be paralleled to increase the output power. There are
no feature included which balances the load current between the DC/DC
converters. Therefore some restrictions and limitations apply. The DC/DC
converter with the higher adjusted output voltage draws current until it goes
into current limitation. This means no harm or switch-off to this DC/DC converter
as long as the ambient temperature stays below 45°C. The CD5.243 can also be
paralleled with power supplies from the DIMENSION CT, QS or QT-series. For
other power supplies consult PULS. Set the “single use / parallel use” jumper to
“parallel use” if such an option is available.
no feature included which balances the load current between the DC/DC
converters. Therefore some restrictions and limitations apply. The DC/DC
converter with the higher adjusted output voltage draws current until it goes
into current limitation. This means no harm or switch-off to this DC/DC converter
as long as the ambient temperature stays below 45°C. The CD5.243 can also be
paralleled with power supplies from the DIMENSION CT, QS or QT-series. For
other power supplies consult PULS. Set the “single use / parallel use” jumper to
“parallel use” if such an option is available.
19/21
the bottom and output terminals on top of the unit).
The output voltages of all DC/DC converter shall be adjusted to the same value
(±100mV) at full load. A fuse or diode on the output of each unit is only required if more than three units are
connected in parallel. This avoid that more than 2 times of the nominal output current can flow backwards into the
DC/DC converter in case the output stage of the DC/DC converter has a defect. If a fuse (or circuit breaker) is used,
choose one with approximately 150% of the rated output current of one DC/DC converter. Keep an installation
clearance of 15mm (left / right) between two DC/DC converters and avoid installing the DC/DC converters on top of
each other. Do not use DC/DC converters in parallel in mounting orientations other than the standard mounting
orientation (input terminals on
(±100mV) at full load. A fuse or diode on the output of each unit is only required if more than three units are
connected in parallel. This avoid that more than 2 times of the nominal output current can flow backwards into the
DC/DC converter in case the output stage of the DC/DC converter has a defect. If a fuse (or circuit breaker) is used,
choose one with approximately 150% of the rated output current of one DC/DC converter. Keep an installation
clearance of 15mm (left / right) between two DC/DC converters and avoid installing the DC/DC converters on top of
each other. Do not use DC/DC converters in parallel in mounting orientations other than the standard mounting
orientation (input terminals on
22.8. P
ARALLEL
U
SE FOR
R
EDUNDANCY
The DC/DC converters can be paralleled for 1+1 redundancy to gain higher system availability. Redundant systems
require a certain amount of extra power to support the load in case one DC/DC converter fails. The simplest way is to
put two DC/DC converters in parallel. This is called a 1+1 redundancy. In case one DC/DC converter fails, the other one
is automatically able to support the load current without any interruption. Redundant systems for a higher power
demand are usually built in an N+1 method. E.g. four DC/DC converters, each rated for 4A are paralleled to build a 12A
redundant system.
require a certain amount of extra power to support the load in case one DC/DC converter fails. The simplest way is to
put two DC/DC converters in parallel. This is called a 1+1 redundancy. In case one DC/DC converter fails, the other one
is automatically able to support the load current without any interruption. Redundant systems for a higher power
demand are usually built in an N+1 method. E.g. four DC/DC converters, each rated for 4A are paralleled to build a 12A
redundant system.
Furthermore, 1+1 redundant systems can be built by using a DC/DC converter powered from a battery and a power
supply with AC input.
supply with AC input.
Please note: This simple way to build a redundant system does not cover failures such as an internal short circuit in
the secondary side of the DC/DC converter. In such a case, the defect unit becomes a load for the other DC/DC
converters and the output voltage can not be maintained any more. This can only be avoided by utilizing decoupling
diodes which are included in the decoupling module YRM2.DIODE.
the secondary side of the DC/DC converter. In such a case, the defect unit becomes a load for the other DC/DC
converters and the output voltage can not be maintained any more. This can only be avoided by utilizing decoupling
diodes which are included in the decoupling module YRM2.DIODE.
Recommendations for building redundant power systems:
a) Use separate input fuses for each DC/DC converter.
b) Monitor the individual DC/DC converter units. A DC-ok lamp and a DC-ok contact is included in the redundancy
module YRM2.DIODE. This feature reports a faulty unit.
c) 1+1 Redundancy is allowed up to an ambient temperature of 60°C
N+1 Redundancy is allowed up to an ambient temperature of 45°C
d) It is desirable to set the output voltages of all units to the same value (± 100mV) or leave it at the factory setting.
Oct 2009 / Rev. 1.0 DS-CD5.243-EN
All parameters are specified at 24V, 4A, 12Vdc input voltage, 25°C ambient and after a 5 minutes run-in time unless otherwise noted.
All parameters are specified at 24V, 4A, 12Vdc input voltage, 25°C ambient and after a 5 minutes run-in time unless otherwise noted.
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