30
The «Smart ECO Mode» operating does not ensure a perfect sta-
bilisation in frequency, voltage or sinewave shape (distortion) as in
«On Line» normal mode, because the figures of these parameters
depend on the static bypass line and preset activation ranges com-
pletely.
The detection of these parameters can take up to 3 ms, so it is rec-
ommended to assess the advisability of using this operating mode,
depending on the level of protection required by the loads.
This operating mode is disabled from factory and the end/user can
activate it, in case it were needed, according to section 7.3.2. and
Fig. 45.
4.4.6. Frequency converter operating.
SLC CUBE3+
can be set from factory as frequency converters,
whether they has batteries or not, being able to operate from 50 to
60 Hz or vice versa.
The equipments set as frequency converters, the static bypass and
manual bypass are not available.
So, those functions, measurements, alarm messages, parameter
settings, as well as manoeuvring of the related switches will not be
operative and they will not be taken into account.
4.5.
OPERATING STRUCTURE OF A PARALLEL SYSTEM.
The Uninterruptible Power Supply Systems
SLC CUBE3+
se-
ries, are designed and thought for its «parallel» connection with a
maximum of four units, on condition that they are the same model
(setting, voltage, power, frequency, back up time, ...), all of them
without adding hardware. Fig. 27 and 28, as an example, show the
circuit diagrams of a three phase/three phase parallel system, with
and without separate static bypass line. Both circuit diagrams are
only showing the input-output power connections and the parallel
control BUS.
A part from the possible setting, conceptually, the parallel systems
are divided in two similar structures and at the same time very dif-
ferent depending on the application.
Systems connected in parallel or active parallel, supply the loads
equally among them. Less when there is only one UPS, the system
will be able to be redundant or non-redundant depending on the
needs and requirements of the application.
•
Simple parallel system (non-redundant)
: a non-redundant
parallel system, is that one where all UPSs supply the required
power by the loads. Total power of the system based on N
equipments of nominal power rate Pn, is N x Pn.
If the system is operating with a load close or equal to the max-
imum and one of them faults, the load will be shifted to bypass
automatically with make before break technique, because it
will not be able to support the consumption demand due to the
overload that it will be caused in the rest of UPSs.
•
Redundant system
: a redundant system is that one has one
or more UPSs than the minimum required by the total power of
the system (depending on the redundancy level), being the load
fair shared among them. So, the fault of any of them will cause
that the damaged UPS will be out of the system and the rest
will continue supplying the load with all the guarantees. Once
the damaged UPS is fixed, it can be connected to the system in
order to recover the redundant condition.
A system with his configuration increases the reliability and as-
sures an AC power supply of quality for the most critical loads.
The quantity of redundant equipments to be connected has to
be studied according to the requirements of the application.
Parallel connection, redundant or not, adds several advantages a
part from the connection itself:
•
Higher punctual power and back up time
: in a parallel
system of N+M equipments, it is considered the nominal max-
imum load of N equipments and +M are the reserve ones, so:
N, is the quantity of equipments in parallel, corresponding to
the minimum quantity required by the total needed power.
+M, is the additional quantity of equipments corresponding
to the residual safety power (redundant equipments).
Although, in practice it can drain the total power in that the N+M
system can supply, the redundancy requirement or conception
does not advice it and in compensation there is a surplus of dy-
namic power against load demands.
I.e., a redundant parallel system with 3 UPS of 40 kVA and N+1
configuration, the nominal maximum load contemplates 80 kVA
(2x40 kVA), although the system can accept load demands up
to 120 kVA (3x40 kVA).
Therefore, the fact of M reserve equipments, increases
the back up time of the set, because the battery set is higher.
•
Modularity
: capacity can be added to a UPS parallel system
by adding equipments of the same feature, without needing to
replace the equipments already installed.
I.e., if time later, an installation with a parallel system of 2 UPSs
is detected that the capacity of this system is not enough, it can
be opted for adding a third equipment to the system, without
replacing the 2 original equipments.
The UPS parallel system management of
SLC CUBE3+
series is
done by a MASTER-SLAVES protocol, where only one equipment
(MASTER) takes the control of the rest ones (SLAVES). So, the con-
trol of the output voltage, bypass shifting, disconnections, mains
synchronisation, ...; are managed by the MASTER equipment, and
transmitted to the SLAVES equipments through the management
bus of the parallel system.
This MASTER or SLAVE condition is dynamic as it is described later
and it will depend on several factors (initial status of the equip-
ments, chronological order of commissioning or shutdown of the
system through one equipment or other one, ...)
USER MANUAL
